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GLOBAL WARNING: CLIMATE CHANGE AND FARM ANIMAL WELFARE

© Compassion in World Farming /Amit Pasricha

A REPORT BY COMPASSION IN WORLD FARMING 2008

CIWF.ORG/GLOBALWARNING

COMPASSION IN WORLD FARMING Compassion in World Farming is the leading international non-governmental organisation specialising in the welfare of farm animals.

Founded by a farmer in 1967, Compassion in World Farming has been highly successful in lobbying for legal reform to protect the welfare of farm animals. Our campaign on animal sentience achieved success in 1997 when a Protocol was added to the European Treaty recognising animals as sentient beings.

Compassion in World Farming produces fully-referenced reports on a range of farm animal welfare issues and related topics, such as the environment and global trade.

Our vision is a world where farm animals are treated with compassion and respect and where cruel factory farming practices end.

We believe that the welfare of farm animals will be best achieved in free range or organic farming systems where their sentience is respected and where they have outdoor access and are kept in smaller groups. Such farms are likely to incorporate a range of environmental benefits, such as protection of biodiversity and reduced pollution and emissions of greenhouse gases.

A complete list of our materials and downloadable versions are available at ciwf.org

© Compassion in World Farming /Xiao Shibai

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GLOBAL WARNING: CLIMATE CHANGE AND FARM ANIMAL WELFARE A report by Compassion in World Farming

2008

"Please eat less meat - meat is a very carbon intensive commodity." Dr Rajendra Pachauri, 15 January 2008, Paris. Chair of the Intergovernmental Panel on Climate Change (IPCC) and joint winner of the Nobel Peace Prize 2007 (reported by ABC News)

Compassion in World Farming River Court, Mill Lane Godalming, Surrey GU7 1EZ, UK Tel: +44 (0)1483 521 950 Email: [email protected]

Fax: +44 (0)1483 861 639 Web: ciwf.org

Registered Charity Number 1095050; a Company limited by Guarantee, registered number 4590804

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CONTENTS EXECUTIVE SUMMARY PART 1:

HOW ANIMAL PRODUCTION IMPACTS CLIMATE & ENVIRONMENT

1.0

INTRODUCTION: CARBON COUNTING FOR LIVESTOCK PRODUCTION

1.1

The unsustainability of current levels of production

1.2

The ongoing explosion in livestock production

1.3

The consensus on reducing livestock-related emissions

1.4

An opportunity for positive change

2.0

MAIN SOURCES OF GHG EMISSIONS FROM ANIMAL PRODUCTION

2.1

Global sources

2.2

Livestock-related emissions in developed countries

3.0

ANIMAL PRODUCTION METHODS AND GREENHOUSE GASES

3.1

Pig and poultry manure

3.2

Soya production

3.3

Animal feed production: land and fertiliser use

3.4

Animal feed production and desertification of pastures

3.5

Resource conflicts due to animal feed production: cereals and water

4.0

DIET, FOOD PRODUCTION A ND GHGS IN DEVELOPED COUNTRIES

4.1

The contribution of meat and dairy production to Europe’s GHGs

4.2

Environmental impact of different animal-based foods

4.2.1

Ruminant and non-ruminant animals

4.2.2

Organic farming

4.3

Energy use and global warming potential associated with choice of diet

PART 2:

BALANCING NEEDS AND SOLUTIONS

5.0

HOW TO REDUCE LIVESTOCK-RELATED GHGS GLOBALLY

5.1

Assessment of some mitigation strategies offered by experts

5.2

Why intensive animal production is the wrong answer

5.3

Why reduction in animal production is the most effective solution

5.4

Opportunities and benefits of a downsized animal production industry

6.0

HOW MUCH DO WE NEED TO REDUCE ANIMAL PRODUCTION?

6.1

Meeting GHG reduction targets

6.1.1

Meat production in developing countries

6.2

Other targets for reducing animal production

6.2.1

Meeting targets to reduce human obesity

6.2.2

Meeting targets to protect and enhance biodiversity

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7.0

HOW COULD MEAT REDUCTION BEST BE ACHIEVED?

7.1

Incorporating carbon costs into production and consumption of animal foods

7.2

Support for consumer decision-making on diet and carbon footprint

7.3

Mandatory targets for reduction in meat production and consumption

7.4

Fiscal incentives for meat reduction

7.5

Protecting purchasing power of low-income consumers

7.6

Strengthening statutory animal welfare standards

8.0

CONCLUSIONS AND RECOMMENDATIONS: COMBATING CLIMATE CHANGE THROUGH HIGH-WELFARE ANIMAL FARMING IN EUROPE

APPENDIX Global production and consumption of animal-based foods

REFERENCES BOXES BOX 1: Summary of main greenhouse gases BOX 2: GHG overview: methane, nitrous oxide and carbon dioxide BOX 3: Further Info Box BOX 4: Projected GHG increases if no action is taken

GLOSSARY AND ACRONYMS FAO

Food and Agriculture Organization of the United Nations

GHG

Greenhouse gas

GWP

Global warming potential, in carbon dioxide equivalent

tonne

1000kg (equivalent to 1.02 ton)

CO2

Carbon dioxide

CH4

Methane

N2 O

Nitrous oxide

N

Nitrogen

P

Phosphorus

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EXECUTIVE SUMMARY Livestock production is responsible for 18% of global greenhouse gas (GHG) emissions from all human activities, measured in CO2 equivalent. This is a higher share than transport, which accounts for 14% of global GHG emissions. Nitrous oxide and methane emissions from animal manure, methane emissions from the animals’ digestion and nitrous oxide emissions from mineral fertiliser used to grow feed-crops for farmed animals make up the majority of this 18%. The livestock sector is responsible for the following proportions of global anthropogenic emissions of the main greenhouse gases:

37% of total methane (CH4) 65% nitrous oxide (N2O) emissions 9% of carbon dioxide (CO2) emissions. In addition, 64% of ammonia emissions originate in livestock production and contribute to air, soil and water pollution, acid rain and damage to the ozone layer. According to the UN Food and Agriculture Organization (FAO), “The livestock sector has such deep and wide ranging impacts that it should rank as one of the leading focuses for environmental policy.”

Meat and milk are currently under-priced in relation to their real environmental and carbon costs. It is essential that the true costs of the livestock industry in relation to climate change are reflected in costs and prices in developed countries.

Compassion in World Farming believes that high-income, developed countries have a situation of unsustainable overproduction and over-consumption of animal products (meat, milk and eggs). We argue that a planned and well-managed reduction in the production and consumption of meat and milk in developed countries, such as those of the European Union, is an essential step in order to help stabilise climate change. We believe that this reduction will have many beneficial side effects for both people and animals and will open up new opportunities to reformulate our food production policies.

UNSUSTAINABLE LEVELS OF ANIMAL PRODUCTION The FAO predicts that between 2001 and 2050, global meat and milk consumption will approximately double. At present, nearly 60 billion animals a year are used globally to produce meat, milk and eggs. This figure could rise to 120 billion by 2050. Such a marked upsurge would have an overwhelming impact on climate change and the environment.

Most of the world’s animal production is carried out in industrial systems that make very heavy demands on natural resources of land and water in order to grow feed-crops for farmed animals. Industrial animal production also causes widespread pollution from animal manure and from the use of fertiliser, pesticides and herbicides. The FAO reports that industrial animal production systems are increasing at six times the rate of traditional mixed farming systems and at twice the rate of grazing systems. At least 50% of the world’s pig meat and over 70% of the world’s poultry meat and eggs are produced in industrial systems.

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Livestock-related GHG emissions are expected to continue to increase rapidly up to mid-century if no action is taken to curb them. The US Environmental Protection Agency considers the key factors in the growth of nitrous oxide and methane emissions to be “the growth in livestock populations … and the trend toward larger, more commercialised livestock management operations.” Emissions from pig slurry and poultry manure are expected to grow strongly as industrialised pig and poultry production expands globally.

ENVIRONMENTAL IMPACT OF I NDUSTRIALISED ANIMAL PRODUCTION Livestock production for meat, milk and eggs uses up an important share of world resources. One third of the world’s total arable land is dedicated to animal feed-crop production; over 90% of the world’s soya beans and 60% of maize and barley are grown for livestock feed. Deforestation is a major cause of CO 2 emissions and loss of biodiversity. Deforestation in South America is largely driven by livestock production; 70% of previously forested land has been converted to livestock pastures and much of the remainder is used to grow feed crops (soya or cereals).

Soya production for feed has tripled since the mid-1980s, often by expansion into new land. Feed-crops are taking over increasingly scarce pasture land, leading to overgrazing and potential desertification of existing and marginal grazing areas. Desertification already affects the livelihoods of more than 25% of the world’s population. According to the FAO, “feed production consumes large amounts of critically important water resources and competes with other usages and users.”

Over-production of livestock will only exacerbate the damage to food production and the environment due to global warming, such as more frequent droughts, floods, storms and harvest failures. In addition, it damages animal welfare, as more animals are subjected to intensive (factory farm) rearing systems, and human health in those countries where there is over-consumption of animal-based foods.

HIGH GLOBAL WARMING POTENTIAL OF ANIMAL-BASED DIETS Meat and dairy production account for 13.5% of total GHG emissions in the EU25. In the UK, meat and dairy account for 8% of total UK emissions, compared to 2.5% for fruit and vegetables. The real global warming potential of meat and dairy production in Europe is even higher than these figures suggest if we include important indirect effects such as deforestation in South America to grow soya beans for animal feed. Diets high in meat and dairy products have much lower energy efficiency and a greater global warming potential compared to diets high in plant-based foods. The energy input for one portion of cooked pork can be three times greater than the energy input for a portion of cooked beans or pulses.

Choices about diet can affect an individual’s carbon footprint as significantly as choices about transport. Increasing the proportion of meat and dairy products in an individual’s diet can be equivalent to the difference between a year’s use of a standard car versus an ultra-efficient hybrid.

These facts have implications for governmental GHG reduction strategies and targets and for the choices made by any individual consumer in order to reduce his or her carbon footprint. Diets high in animal products increase GHG emissions and increase an individual’s carbon footprint. Diets high in plant products save energy and reduce an individual’s carbon footprint.

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WHY A REDUCTION IN MEAT AND MILK PRODUCTION IS ESSENTIAL Strategies proposed by the Intergovernmental Panel on Climate Change to reduce livestock-related GHGs could probably only reduce emissions by less than 20%. These strategies include reforestation, restoration of carbon soils, more careful and targeted use of fertilisers and disposal of manure. Such measures are clearly necessary, but are unlikely to make a large enough reduction in GHGs in a short time period. Other proposed strategies aim at the digestion or excretion of the animals themselves, such as feeding more grain and less forage (to reduce methane production) or chemical treatment of the animals. These could be very problematic if they lead to adverse effects on the animals’ digestion or health. In any case, they are unlikely to be feasible for the majority of small farmers globally.

The leading sources of livestock-related GHG emissions originate in the natural biological processes of each animal (digestion, excretion). A reduction in the size of the livestock industry in developed countries is therefore the simplest, quickest and probably the only effective method of cutting GHGs from animal production to the extent that is necessary to limit the future increase in global warming.

WHY INTENSIVE ANIMAL PRODUCTION IS THE WRONG ANSWER Some agriculturalists propose intensifying animal production in order to increase yield per animal and hence reduce the GHG emissions per unit of output. Compassion in World Farming considers that intensification is a deeply flawed strategy from the point of view of halting climate change and from environmental and animal welfare considerations. It would also be ethically and politically unacceptable to consumers in developed countries, where concern about the welfare and environmental effects of farming, and the demand for free-range and organic animal products, is increasing fast.

Intensification would almost certainly mean an increase in factory farming of pigs and poultry and a reduction in free-range animals, including grazing cattle and sheep. It would often be counterproductive as already high-yielding animals were pushed even further for higher yields, leading to increased stress and ill-health, shorter productive lifetimes of dairy cows and breeding sows and increased potential for the spread of infectious disease. The increased demand for feed would put more pressure on land and water resources globally and increase pollution from manure and agrochemicals.

Compassion in World Farming believes that, rather than calling for “more of the same”, agriculturalists and policy makers should look afresh at the whole issue of how we should rear animals for food in ways that protect the nutritional needs of people, the livelihoods of farmers, the welfare of farmed animals and the global climate and environment.

BENEFITS FOR HUMAN HEALTH Recent estimates from public health experts suggest that a reduction of around 60% in daily intake of meat in developed countries would help reduce excess weight and obesity and offer other health benefits to individuals and society. Reducing consumption of red and processed meats is also recommended by the World Cancer Research Fund in its 2007 Report, which cites these meats as convincing causes of colorectal cancer.

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PROPOSED TARGETS AND STRATEGY FOR MEAT AND DAIRY REDUCTION IN EUROPE In line with current UK and European GHG emission reduction targets, which may need to be increased in view of new scientific evidence, Compassion in World Farming believes that the European Union and other high-income, developed countries should reduce production and consumption of meat and milk to one third below current levels over the next decade (by 2020) and to at least 60% below current levels by 2050. Under our proposals: Consumers would eat a lower volume of higher quality meat and milk, preferably from local farmers. Farmers would earn a premium for their products, and higher prices would reflect the carbon costs of consuming meat and milk A reduction of one third would be roughly equivalent to an individual who eats meat daily eating meat on only five days a week, or alternatively reducing portion sizes of meat and dairy products and substituting plant-based foods such as pulses, grains, vegetables and fruit Farmers would be enabled to reduce stocking density, move from intensive to extensive methods and raise animal welfare standards up to the best free-range and organic farming standards of today, while protecting their livelihoods. Imported products would be required to meet the same standards. Governmental and intergovernmental targets and incentives for both producers and consumers would be needed to support this transition, including protecting the purchasing power of low-income consumers. The benefits of this strategy are many, in addition to going a long way to meet the urgent task of reducing GHG emissions: -

A significant reduction in meat and dairy consumption would improve public health and reduce the prevalence of obesity, certain heart conditions and cancers. This would have a positive impact on related health care costs.

-

Localisation of animal production and consumption would support rural communities and businesses.

-

Reduction in demand for animal feed would allow a reduction in the intensity of arable farming and increase farmland biodiversity.

-

The strategy would also lead to the end of animal factory farming and enable a revolution in standards of farm animal welfare.

In order to achieve a global and proportionate reduction in the production and consumption of meat and dairy products, Compassion in World Farming calls on all governments to negotiate an International Treaty on Meat and Dairy Reduction, or to incorporate meat and dairy reduction targets or production caps into any future climate change agreement. Such a treaty or agreement will set fair reduction targets for high-income countries, while allowing the poorer developing countries to enhance their small-scale livestock farming.

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PART 1: HOW ANIMAL PRODUCTION IMPACTS ON CLIMATE AND ENVIRONMENT 1.0

INTRODUCTION: CARBON COUNTING FOR LIVESTOCK PRODUCTION

A huge increase in the global use and consumption of farmed animal products is currently taking place and is predicted to continue up until the mid-century. Between 1995 and 2005, the number of mammals used globally per year to produce meat and milk increased by 22% to 4.1 billion and the number of poultry used to produce meat and eggs increased by 40% to 57.4 billion. Of the total net world increase in annual production (tonnes of product) 87% was in developing countries1, where meat consumption per person is still on average only a tenth of that in high-income countries. 2 This continuing increase comes at a time of climate change when it is recognised that we are living through a crisis in the impact of humans on the planet’s climate. This report presents the evidence from climate scientists and agriculturalists showing that livestock production has made, and is making, a major contribution to the total human-induced (anthropogenic) global warming effect. While comparable in magnitude to emissions from transport, the livestock source has been so far neglected by current GHG reduction policies that focus on energy-related CO2 emissions. This report aims to re-balance the debate and sets out what should be done to halt the impact of animal production on our climate, while at the same time protecting the nutritional needs of people, the livelihoods of farmers, the welfare of farmed animals, the environment and biodiversity. Compassion in World Farming believes that in high-income, developed countries we now have a situation of unsustainable overproduction and over-consumption of animal products (meat, milk and eggs). This is being brought even more sharply into focus by the fact of climate change. While lowincome countries and some fast-developing countries are expected to continue their rapid growth in animal production, it is essential that the growth of global livestock-related greenhouse gas (GHG) emissions is curbed in the short term. We argue that a planned and well-managed reduction in the production and consumption of meat and milk in developed countries, such as those of the European Union, is an essential step in order to help stabilise climate change. We believe that this reduction will have many beneficial side effects for both people and animals and will open up new opportunities to reformulate our food production policies.

1.1

THE UNSUSTAINABILITY OF CURRENT LEVELS OF ANIMAL PRODUCTION

Current animal production is responsible globally for 18% of all human-induced GHG emissions, according to the UN Food and Agriculture Organisation (FAO) 3. This is higher than the 14% contributed by all transport4 which includes transport by road, air, rail and shipping. Of the three major greenhouse gases, animal production accounts for 65% of all anthropogenic emissions of nitrous oxide (N2O), 37% of all anthropogenic emissions of methane (CH4) and 9% of all anthropogenic carbon dioxide (CO2) globally5 (see TABLE 1). It is estimated that the emissions due to meat and dairy production and consumption account for 8% of total anthropogenic GHG emissions in the UK6 and about 13.5% of total EU25 emissions, according to the European Commission’s 2006 Environmental Impacts of Products (EIPRO) assessment7,8. 10

TABLE 1: Summary of the contribution of animal production to global GHG emissions Source unless otherwise stated: Steinfeld et al, 20063 SOURCE OF EMISSION

PERCENTAGE CONTRIBUTION OF SOURCE TO TOTAL OF GLOBAL HUMAN-INDUCED GHGS

Total GHG emissions from animal production

18% of total human-induced GHG emissions

Compare: GHG emissions from transport (road, air, rail

14% of total human-induced GHG emissions

4

and sea)

Compare: GHG from all power works and generation

24% of total human-induced GHG emissions

4

(oil, gas, coal)

Carbon dioxide (CO2) emissions from animal

9% of total human-induced CO2 emissions

production Methane (CH4) emissions from animal production

37% of total human-induced CH4 emissions

Nitrous oxide (N2O) emissions from animal

65% of total human-induced N2O emissions

production Ammonia emissions from animal production

64% of human-induced ammonia emissions (Not classified as a GHG but contribute to nitrous oxide, eutrophication, acidification and ozone depletion. See FURTHER INFO BOX)

The environmental costs of our current and future levels of animal production come not only from the emission of GHGs but also from overuse of natural resources. These include over-exploitation of land and water, pollution by manure and fertiliser leading to such effects as eutrophication of soil and water, acidification and damage to the ozone layer; soil degradation and desertification of pastures; loss of biodiversity from pollution and habitat destruction. All these additional damaging effects can only exacerbate any inevitable effects of climate change (drought, floods, harvest failures, high cereal prices, etc.). Apart from the environmental unsustainability of the current global level of animal production, it is widely accepted that a western diet, including over-consumption of energy-dense foods such as animal products, is fuelling a global crisis of overweight and obese individuals in both developed and developing countries.9, 10 Climate change has a long timescale; unlike some other forms of pollution, past and current emissions of GHGs will continue to have an effect well into the future and the results will only become clear long after the emissions have occurred. This makes it essential for us to take action to reduce GHG emissions now rather than later. Livestock production has a major role to play in this. The evidence collected in this report shows clearly that it is impossible to control GHG emissions from this important sector and to conserve natural resources and biodiversity if developed countries maintain their current over-consumption of animal products. Similarly, it is clear that it would not be sustainable for developing countries to increase their meat, milk and egg consumption up to the current levels of developed countries, from the point of view of climate, exploitation of natural resources, protection of biodiversity or human health. The scale of the livestock industry’s use of global resources is shown in TABLE 2, taken from the FAO’s 2006 review. 5

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TABLE 2: Global resource use and environmental impacts related to animal production3, 5, 11, 12 Source unless otherwise stated: Steinfeld et al, 20063

RESOURCE

ENVIRONMENTAL IMPACTS

Animal production as proportion of all agricultural

40% of total

output Meat & milk animals as proportion of all land animals

20% of all land animal biomass

Use of land for animal production

30% of earth’s land area, mostly for permanent pasture, also for feed-crops

Use of land for animal pasture

26% of earth’s land area

Use of cropland for animal feed-crops

33% of all cropland or 4% of earth’s land area

Use of cereals for animal feed

About 1/3 of all cereals harvested3 (others have estimated higher, eg: over 50% of wheat and barley in UK

Use of maize and barley for animal feed

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60% of total maize and barley produced (data up to 2001)

Use of soya for animal feed

97% of soya meal produced (ie ~70% of soya beans produced)

Use of water for animal production

8% of total human water use; of which 7% for feed production, remainder for drinking, cleaning and slaughter/processing

Pastures and rangelands degraded because of

20% of total pasture land including 73% of dry

overgrazing, soil compaction and erosion

rangelands

Proportion of former Amazon forest that is occupied by

70% of deforested area is used for pasture and a

grazing and feed-crops

large part of remaining deforested area is used for

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14 feed-crops .

Proportion of water pollution from nitrogen (N) &

In US: 33% for N and 32% for P. In China-

phosphorus (P) due to livestock production (manure,

Guangdong: 72% for N and 94% for P

fertilisers)

BOX 1: Summary of main greenhouse gases Source: Steinfeld et al, 2006, Tables 3.1 and 3.1215 Proportion of

Current

Increase since

Lifetime in

Global

all animal-

concentration in

pre-industrial

atmosphere

warming

production

atmosphere

era (mid

potential

GHG

(troposphere)

18thC)

(GWP)

(CO2 equiv.)

relative to CO2

Carbon

38%

dioxide

382 parts per

+38%

million

5 – 200 years

1

(ref. 16)

(CO2) Methane

31%

(CH4) 31%

1728 parts per

+188% (nearly

billion

trebled)

318 parts per billion

Max. +18%

Nitrous oxide (N2O) 12

9 – 15 years

23

114 years

296

1.2

THE ONGOING EXPLOSION IN LIVESTOCK PRODUCTION

Since 1980, according to the UN’s Food and Agriculture Organisation (FAO) the global production of pigs and poultry has quadrupled and the production of cattle, sheep and goats has doubled. Even in the 10 years between 1995 and 2005 the global number of meat chickens reared annually increased by nearly 14 billion (an increase of 40%), the number of egg laying hens used increased by 2.3 billion (a 31% increase), the number of pigs reared for meat rose by 255 million (an increase of 24%) and the number of cows used for milk production increased by 12 million (an increase of 6%). 1 All these animals need to eat, digest and excrete and the production of their feedstuffs and disposal of their manure are increasingly challenging the global environment. The FAO predicts that this increase in animal production will continue and that meat production will double again and milk production will increase by 80% by 2050, on current trends.3 The intensification and industrialisation of animal farming has played a major role in this expansion of output. Industrial production has taken over, or is currently taking over, from backyard or peasant animal keeping, pastoralism or small commercial farmers around the world. According to the Worldwatch Institute, in 2004 industrial systems generated 74% of poultry meat, 50% of pig meat, 43% of beef and 68% of eggs globally. 17 The FAO’s estimates for industrial pig and poultry production are similar, at 55% and 72% of total production respectively. 5 The FAO reports that industrial animal production systems are increasing at six times the rate of traditional mixed farming systems and at twice the rate of grazing systems.18 The future problem of burgeoning GHG emissions from livestock production will be fueled by the growth of intensive and industrial systems that damage both the environment and animal welfare.

TABLE 3: Global industrialised animal production as a proportion of world supply of pig and poultry products PRODUCT

PROPORTION FROM INDUSTRIAL SYSTEMS 5,17

Poultry meat

72 – 74%

Pig meat

50 – 55%

Eggs

68%

1.3

THE CONSENSUS FOR REDUCTION LIVESTOCK-RELATED EMISSIONS

The FAO and the Intergovernmental Panel on Climate Change (IPCC) expect livestock-related GHG emissions to continue to increase rapidly up to the mid-century unless action is taken to reduce them.5, 19 As with other economic sectors, the majority of these emissions will come from developing countries as their production and consumption increases towards the levels of developed countries. The following are expert views on the impact of livestock production on climate change and the environment and the need to reduce that impact:

Food and Agriculture Organization of the United Nations (FAO) The FAO concluded perhaps the most detailed study ever made of the environmental impact of livestock production by stating that ‘business as usual’ is not an option and that: 14 • ‘The environmental impact per unit of livestock production must be cut by half, just to avoid increasing the level of damage beyond its present level’ • ‘[T]he livestock sector has such deep and wide ranging impacts that it should rank as one of the leading focuses for environmental policy’ 13

‘A top priority is to achieve prices and fees that reflect the full environmental costs [of livestock production], including all externalities’

Intergovernmental Panel on Climate Change (IPCC) The IPCC’s 2001 Technical Summary of Working Group 3 (mitigation) report states: ‘A shift from meat towards plant production for human food purposes, where feasible, could increase energy efficiency and decrease GHG emissions (especially N2O [nitrous oxide] and CH4 [methane] from the agricultural sector).’ 20 The IPCC’s 4th Assessment Mitigation report (to be finalised in November 2007) concluded in Chapter 8 on Agriculture: ‘Greater demand for food could result in higher emissions of CH4 [methane] and N2O [nitrous oxide] if there are more livestock and greater use of nitrogen fertilizers … Deployment of new mitigation practices for livestock systems and fertilizer applications will be essential to prevent an increase in emissions from agriculture after 2030.’ 21

UK (Westminster) government The ‘Greener Eating’ website advises consumers that: ‘The production of meat and dairy products has a much bigger effect on climate change and other environmental impacts than that of most grains, pulses and outdoor fruit and vegetables.’ 22

The current consensus among climate change scientists and policy makers is that emissions need to be cut sufficiently to keep the future global temperature rise to around 2ºC and that this will require reducing global GHG emissions by mid-century by well over 50%;23 some UK experts believe that reductions of up to 90% by 2050 and 70% by 2030 are required.24

Currently the UK and the EU are not on track to

meet these targets.

1.4

AN OPPORTUNITY FOR POSITIVE CHANGE

The urgent need to reduce GHG emissions and the other environmental impacts of animal production will require big changes in the livestock industry of developed countries such as those of the EU and North America. Compassion in World Farming believes this fact should be seen as an opportunity rather than as a threat. In Europe during the 20th century the intensification of agriculture was strongly encouraged by governments in order to increase food supply, and did so very successfully. But for long after there was a need to increase food supply, animal farmers in developed countries have continued to focus on the goals of increasing production and reducing costs in ways that made both them and the general public increasingly uneasy. In the livestock production industry, this drive for efficiency also led to the adoption of the battery cage, the veal crate, the sow stall (gestation crate) and the broiler shed that are now symbols of the unacceptable face of factory farming. Evidence has piled up about the damaging results for the environment and animal welfare. Public pressure has led to the legislative phase-out of barren battery cages, veal crates and sow stalls throughout the EU and the start of an industry-led phase-out in North America. In the current global market, the route of competing with developing countries for lowest cost per unit output is almost certainly a dead end for European livestock farmers.

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Many farmers would prefer to be able to farm in a more animal-friendly and environmentally-friendly way but the current market climate of low costs often makes that seem impossible. Meanwhile, consumers in developed countries are increasingly looking for animal products from free-range and organic systems. Compassion in World Farming believes that the urgent need to reduce GHG emissions and other environmental damage due to livestock farming offers a way to break with the past and offer both farmers and consumers a route to an animal production system that respects both animal welfare and the global climate.

2.0

THE MAIN SOURCES OF GHG EMISSIONS FROM ANIMAL PRODUCTION

2.1

GLOBAL SOURCES

The major global warming potential of livestock production worldwide, even in developed countries, comes from the natural life processes of the animals. Unlike other economic sectors, CO2 emissions from animal production-related fossil fuel use are much lower than the non-CO2 emissions from the natural and unavoidable bodily functions of animals (feeding, digestion and excretion).

FIGURE 1: Percentage global contribution of major sources of livestock-related GHGs Source of data: Steinfeld et al, 2006, TABLE 3.12

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Percent contribution to total livestock-related GHGs

Enteric 25.3%

Other 4.1%

Deforestation 34.0%

Fertiliser 6.2%

Manure 30.4%

Livestock-related GHG emissions arise from mainly from following sources (also see Summary Table 7 for further details):5 Production of animal manure that is deposited in fields or in animal housing by the animals, stored on farm and then disposed of by being spread on fields or pastureland. Manure releases both methane (CH4) and nitrous oxide (N2O). According to the FAO, ‘[M]anure-induced soil emissions are clearly the largest livestock source of N2O [nitrous oxide] worldwide’.5 All manurerelated emissions are about 30% of livestock-related emissions and over 5% of total anthropogenic GHGs The digestive processes of the animals, particularly ruminants such as cattle, sheep and goats. The ‘enteric fermentation’ process by which ruminant animals digest fibrous feed releases large

15

amounts of methane (CH4). Enteric fermentation emissions account for about 25% of livestockrelated emissions and about 4.5% of all anthropogenic GHG emissions The production of animal feed (crops and grassland). Around 1/3 of the world’s total cereal crop and over 90% of the world’s soya crop is grown for animal feed. Feed-crops require the use of land, fertilisers, machinery and transport. Carbon dioxide is emitted during the manufacture of mineral (N) fertiliser and nitrous oxide is emitted from mineral fertiliser used on land. The manufacture and use of fertiliser for producing animal feed accounts for over 6% of all livestockrelated GHG emissions Deforestation (currently mainly in South America) for cattle grazing and/or for the production of soya beans or cereals for animal feed. Deforestation releases large amounts of CO2 previously stored in vegetation and soil. Deforestation for animal production accounts for 34% of all livestock-related GHG emissions and over 6% of all human-induced GHG emissions. Globally, the most important single contributions to livestock-related GHGs are deforestation (34% of total) followed by CH4 from enteric fermentation and manure-related N2O (each around 25% of total); see FIGURE 1 above. It is notable that livestock manure and enteric fermentation alone account for 10% of all anthropogenic GHG emissions (TABLE 4), five times the proportion of global emissions due to air transport.4 TABLE 4: Relative importance of different sources of GHGs from animal production Adapted from Steinfeld et al, 2006, Table 3.12 5 LIVESTOCK RELATED GHG OR SOURCE

WHICH

% OF ALL

% OF ALL

% OF ALL

GHG

HUMAN

LIVESTOCK

HUMAN-

EMISSIONS

GHGs

INDUCED

FOR GHG

GHGs

SPECIFIED 18

ALL LIVESTOCK GHG CH4

37

31

5.5

N2 O

65

31

5.5

CO2

9

38

6.8

7.7

34

6.1

-----

30.4

5.5

DEFORESTATION

CO2

ALL MANURE RELATED, OF WHICH: Manure management (esp. slurries)

CH4

6.3

5.2

0.93

Manure (deposition, application, manage etc.)

N2O

52.6

25.2

4.5

ENTERIC FERMENTATION

CH4

30.5

25.4

4.5

------

6.2

1.1

ALL N FERTILISER RELATED, OF WHICH: N fertiliser production

CO2

0.13

0.56

0.1

N fertiliser use [1]

N2O

11.8

5.6

1.0

DESERTIFICATION OF PASTURES

CO2

0.32

1.4

0.25

SOIL CULTIVATION FOR FEED

CO2

0.1

0.42

0.08

FOSSIL FUEL USE ON FARM

CO2

0.29

1.27

0.23

PROCESSING

CO2

0.16 max.

0.7 max.

0.13 max.

TRANSPORT

CO2

0.003

0.01

0.0025

[1] includes leguminous feed-cropping (eg: soya, clover, alfalfa)

16

2.2

LIVESTOCK-RELATED EMISSIONS IN DEVELOPED COUNTRIES

It is an important fact that even in industrial countries the majority of livestock-related GHG emissions arise from the digestion and excretion of the animals. Developed countries tend to have a much higher proportion of intensive animal production which results in higher emissions of carbon dioxide from fossil fuel energy use. The use of concentrate animal feeds, based on cereals and soya, and the manufacture of fertiliser for feed crops and pasture, increase the CO2 emissions from intensive farming in developed countries compared to developing countries. In spite of this, the majority of emissions from animal production in developed countries are methane from enteric fermentation and methane and nitrous oxide from manure, as the following examples show. In the EU15, methane and nitrous oxide from agriculture make up 9% of total anthropogenic emissions of GHGs. These come mainly from the animals’ enteric fermentation and manure and from the use of N fertiliser (typically half of this is used for animal feed production in developed countries and the remainder for crops used directly for human food).25 In the UK, methane and nitrous oxide make up over half of total GHG emissions related to animal products (pig meat, poultry meat, beef, sheep meat, milk and eggs). For pig meat, poultry meat and eggs, which are all likely to be produced in intensive systems, carbon dioxide emissions make up a relatively higher proportion (45-47% of the total).6, 26 In Ireland, studies of typical milk production on dairy farms have also shown that digestion and manure are around 60% of total, rather than from fossil fuel energy use (5%) or concentrate feed production (13%).27

TABLE 5: Relative importance of sources of GHG emissions from milk production in Ireland Source: Casey and Holden, 2005.27 SOURCE DURING PRODUCTION

% of total emissions for dairy

(up to farm gate)

production

Enteric fermentation

49%

Fertiliser-related

21%

Concentrate feed, including imports

13%

Manure management

11%

Electricity and diesel

5%

In Belgium, methane and nitrous oxide make up 76% of the total GHG emissions related to meat production.28 In the US, well over 95% of agricultural methane and nitrous oxide emissions originate from animal digestion and manure or fertiliser use29 (and about half of all US fertiliser use is for animal feed production5). In the Netherlands, 70% of agricultural methane emissions are from enteric fermentation and 30% from liquid manure management (nearly all Dutch pig production uses slurry systems).30

17

TABLE 6: Major sources of GHG emissions in US animal production Source: US-EPA Greenhouse gas inventory, 2007. 29 % of all agricultural

% of total US

emissions for

emissions for that

specified GHG

GHG

97%

78%

2.5%

2%

Enteric fermentation (95% from beef & dairy)

69.5%

21%

Manure management (slurries)

25.6%

8%

N2 O Agric soil management (N fertiliser use and deposition or application of manure to land plus results of ammonia emissions) Manure management

CH4

In Japan, a 2007 study of the lifetime GHG emissions in the production of a beef calf showed that methane from enteric fermentation alone accounted for over 61% of the total emissions of production, while feed production and feed transport accounted for nearly 27%.31 These examples emphasise that GHG emissions from animal production, even in developed countries where energy use in animal production is relatively high, mostly arise from the natural life processes of the animals and therefore are difficult to reduce other than by reducing the size of the animal production industry.

Table 7 on the next three pages summarises the livestock-related sources of GHGs globally.

18

TABLE 7: Summary of livestock-related sources of GHGs globally. Source: Steinfeld et al, 2006.5 LIVESTOCK-

GLOBAL QUANTITY OF

FURTHER DETAILS ON SOURCE &

RELATED SOURCE

LIVESTOCK-RELATED GHG

EFFECTS

OF GHG

EMITTED PER YEAR For methane & nitrous oxide (CH4 & N2O) see TABLE 4 for CO 2 equivalents

Fossil fuel use for N

The Haber-Bosch process [1] uses 1% of

41 million tonnes CO2

fertiliser manufacture for

world’s energy to produce mineral nitrogen

feed production

fertiliser (for all uses, not only for animal feed). Mostly natural gas used, but 60% of China’s fertiliser production is coal-based.

Fossil fuel use for on-

60 million tonnes CO2 for feed

Includes feed production and transport,

farm animal rearing

production; 30 million tonnes CO2

forage, concentrates, seed,

for on-farm livestock management

herbicides/pesticides, diesel for machinery (land preparation, harvest, transport, electricity (irrigation pumps, drying, heating, cooling). In US, more than half of energy is for feed production.

Deforestation & other

2.4 billion tonnes CO2

Destruction of forests or other wilderness

land use changes

for conversion to pasture or feed-cropping.

related to livestock

The main drivers are cattle grazing and

production

soya production in South America. Also CH4 oxidation ‘greatly’ reduced

33

The carbon in CH 4 in soils is utilised by soil microorganisms (by oxidation) and hence removed from soils; this is greatly reduced in pastures compared to forests.

Cultivation of land for

5

C stored (sequestered) in soils is twice that

28 million tonnes CO2

feed crops, mostly large-

stored in vegetation or in the atmosphere.

scale intensive

C in soils is lost naturally by mineralisation

management

and decomposition, but this is increased by human disturbance, when natural cover is changed to managed land. Tillage reduces soil organic (carbon) material and emits CO2.

Desertification of

100 million tonnes CO2

Due to decline of soil organic carbon and

pastures

erosion; (In Argentina, desertification resulted in 25-80% decrease in soil organic 5 carbon in areas with long-term grazing. )

Respiration by livestock

-----

Eg: animal breathing. Not considered a net source of CO2 under Kyoto Protocol. Animal bodies could be considered a carbon store (carbon sequestration) but this is ‘more than offset’ by methane emissions which increase correspondingly. 19

5

TABLE 7 continued: Summary of livestock-related sources of GHGs globally. LIVESTOCK-

GLOBAL QUANTITY OF

FURTHER DETAILS ON SOURCE &

RELATED SOURCE

LIVESTOCK-RELATED GHG

EFFECTS

OF GHG

EMITTED PER YEAR For methane & nitrous oxide (CH4 & N2O) see TABLE 4 for CO 2 equivalents

Enteric fermentation

Methane is created as by-product in the

86 million tonnes CH4

(part of digestive

fore-stomach (rumen) of ruminants (cattle,

process)

sheep etc.) and is also produced to lesser extent by pigs (monogastrics). ‘Enteric fermentation’ refers to the process by which stomach bacteria convert fibrous feed into products that can be digested by the animal. This can be a large contribution to total CH4 emissions: over 70% of total CH4 (all sources) for Brazil in early 1990s and 70% of agricultural CH4 emissions in US (in both cases mostly due to beef and dairy 5

production). Animal manure (mainly

CH4 created by anaerobic decomposition of

18 million tonnes CH4

liquid manure slurry)

manure (ie: not in presence of oxygen, for example when liquid or wet. See Further

Mainly due to intensive

Info Box). Arises from management of

and industrial systems

liquid manure in tanks and lagoons, which

(FAO 2006, section

are typical for most large-scale pig

3.5.3)

operations over most of the world (FAO 2006) and large dairy operations in North America and Brazil. Dry manure stored or spread on fields does not produce significant amounts of CH4.

Mineral N fertiliser

0.2 million tonnes

Plants assimilate at best 70% of added N

application for feed

N2O-N (ie N in form of N2O)

(absorption better from mineral fertiliser than from animal manure) leaving 30%

production

inherent loss of the added N to environment. Estimated that 20-25% of total mineral N fertiliser is used for feed 5 production. Mineral fertiliser is not used in

organic farming. Emissions from

0.5 million tonnes N2O-N (ie: N in

Includes growing of soya bean, alfalfa,

leguminous feed-crops

form of N2O)

clover. These crops are less likely to be fertilised with N fertiliser but produce the same level of N2O emissions as nonleguminous N-fertilised crops.

20

TABLE 7 continued: Summary of livestock-related sources of GHGs globally. Source: Steinfeld et al, 2006.5 LIVESTOCK-

GLOBAL QUANTITY OF

FURTHER DETAILS ON SOURCE &

RELATED SOURCE

LIVESTOCK-RELATED GHG

EFFECTS

OF GHG

EMITTED PER YEAR For methane & nitrous oxide (CH4 & N2O) see TABLE 4 for CO 2 equivalents

Nitrogen emissions from

0.2 million tonnes N2O-N

This results from about 8–10 million tonnes

aquatic sources due to

5 N/year that is lost into water as a result of

use of N fertiliser

the use of N fertiliser on land used for animal feed and forage.

Ammonia (NH3)

3.1 million tonnes NH3-N (ie N in

Can be converted to N2O in atmosphere or

volatilisation from

form of ammonia)

when re-deposited. Also leads to

mineral N fertiliser for

eutrophication [3], acidification [4] and

feed [2]

ozone depletion.

Stored animal manure

0.7 million tonnes

Excretion in animal houses, collection and

(mostly dry manure but

N2O-N (N in form of N2O)

storage. Emissions higher for dry manure

also emissions from

(can be 15% of N content). Losses during

slurries)

storage from deep litter can be 150 times the losses from slurries. Includes N2O emissions from surface of slurries and from slurries spread on land.

Ammonia from manure

2 million tonnes NH3-N

Generated in ‘confined animal feeding

storage in intensive

operations’ (eg: from poultry manure).

systems Manure-induced ‘direct’

1.7 million tonnes N2O-N

Excreta freshly deposited on land (either by

N2O emissions from soil

animals or applied by spreading). ‘[M]anure-induced soil emissions are clearly the largest livestock source of N2O 5

worldwide’. Manure-induced

Up to 1.3 million tonnes N2O

‘indirect’ N 2O emissions

Indirect emissions following volatilisation and leaching of N unused by crops and intensive grassland. Majority from mixed systems.

Livestock processing

Several tens of million tonnes CO2

Transport, slaughter, etc. milk processing (pasteurisation, cheese and dried milk)

Transport and

0.8 million tonnes CO2

Delivery of processed feed to animal

distribution

production sites and transport of products to retailers and consumers. Soya bean is a notable long-distance feed trade; estimate of annual soya bean cake shipped from Brazil to Europe emission is 32,000 tonnes of CO2.

21

5

[1] The Haber-Bosch process is an industrial chemical procedure using extremely high pressures and high temperature to produce ammonia from atmospheric nitrogen gas (a process known as ‘nitrogen fixation’). The ammonia is then used to produce mineral fertiliser. [2] Volatilisation is the process whereby a substance changes from a solid (or liquid) form to a gas form. Here it refers to the emission of gaseous ammonia from mineral N fertiliser (see Further Info Box). [3] Eutrophication refers to excessive enrichment of an environment (soil, water) by nutrients (in this case nitrogen but also can be phosphorus). See Further Info Box. [4] See Further Info Box.

3.0

ANIMAL PRODUCTION METHODS AND GREENHOUSE GASES

Intensive animal production systems are taking over from small scale, traditional animal production globally. Much of the global GHG emissions currently arise from enteric fermentation and manure from grazing animals and traditional small-scale mixed farming in developing countries. Half of the world’s pigs are reared in China, the majority still in non-commercial farms. By contrast, in developed regions and to a lesser extent in some rapidly industrialising countries, nearly all of the pig and poultry production and some milk and beef production, is highly intensive and often industrialised. According to the FAO, about 80% of the total growth in livestock production comes from industrial rearing systems.32 Therefore it is worth examining the effect these will have on future GHG emissions. Intensive and industrial systems have enormously increased the numbers of animals farmed globally and will continue to do so. Being high-input, concentrated systems, they are very demanding of resources of land, water, fertiliser and feedstuffs and produce large quantities of manure on relatively small areas of land. The quantity of manure produced is likely to be very much more than the land can absorb usefully, leading to N and P pollution and nitrous oxide emission. If animal numbers and intensification continue to increase we can expect GHG emissions from these systems to become the dominant ones from a global point of view.

3.1

GHGs FROM PIG AND POULTRY MANURE

Industrial production of pigs and poultry is an important source of GHG emissions and is predicted to become more so. On intensive pig farms, the animals are generally kept on concrete with slats or grates for the manure to drain through. The manure is usually stored in slurry form (slurry is a liquid mixture of urine and faeces). During storage on farm, slurry emits methane and when manure is spread on fields it emits nitrous oxide and causes nitrogen pollution of land and water. Poultry manure from factory farms emits high levels of nitrous oxide and ammonia.

In 2006, the US Environmental Protection Agency (US-EPA) published a survey and predictions of global agricultural methane and nitrous oxide emissions. The report considers that: ‘The key factors influencing both methane and nitrous oxide emissions in this category are expected to be the growth in livestock populations necessary to meet the expected worldwide demand for dairy and meat products and the trend toward larger, more commercialized livestock management operations.’ The report anticipates a ‘transformation of management systems from dispersed, pasture operations to largersized, commercialised production … Such transformations are occurring now throughout the developing world and will likely increase emissions, particularly in Africa and Latin America.’ 34 The transformation of 22

pig production to commercialised units, especially in China and Brazil, will increase animal numbers and also the use of slurry systems for manure collection, so that ‘the trend will likely be toward increasing methane emissions.’ 34 According to the FAO, pigs and poultry currently account for 77% of the increase in animal production in developing countries.5 A survey and analysis of the emissions from the EU (15 Member States only) by the European Commission shows that the use of slurry systems for pigs and dairy have actually increased by a few percentage points since 1990, an indication of intensification. Pig production in Europe has a high potential for emitting methane from manure, due to the fact that 82% of pig production uses liquid (slurry) manure systems.25 In poultry production, the EPA expects that ‘ increases in worldwide poultry production, estimated to have the fastest rate of growth of all livestock types (over 26 %) over the next decade…., will in particular drive increases in nitrous oxide emissions because of the relatively high nitrogen content of poultry waste and the management systems used’. Increases in nitrous oxide emissions due to increased poultry production are expected in China, south and east Asia and South and Central America and also in the US.34

3.2

SOYA PRODUCTION

The demand for soya as a high protein feed is a major cause of livestock-related climate change. One of the most important causes of global warming is deforestation (6% of global anthropogenic GHGs). One of the two main drivers for deforestation in South America, particularly Brazil, is the demand for soya production for animal feed.33 Well over 97% of soya bean cultivation is primarily for feed purposes (the soya meal left when oil has been extracted from the bean is used as animal feed). It is estimated that 70% of previously forested land is used for pasture and much of the remainder is used to grow soya,14, 33, 35

to be used in regions of intensive livestock production (such as in Europe and China).

Soya meal makes up around 10-20% of the feed of chickens and pigs across a range of developed and developing countries, including China, Brazil, Japan, the US, Germany, Mexico, Thailand and the UK. 36 It is also used as a high protein feed for dairy cattle, especially after the banning of animal protein from feed after the BSE epidemic. Soya is part of a globalised animal feed trade. In response to demand for animal feed, soya bean production has tripled since the mid-1980s and half of the total increase took place in the five years up to 2006.35 Much of this huge increase has been achieved by expanding the area of cropped land. In 2003, WWF Brazil reported on an export-led soya bean production boom that has taken place in the ecologically sensitive Cerrado (savannah) region of centre-west Brazil.35,37 To set up the soya plantations, large production companies bought land from smallholders but WWF found that production ‘also involves expansion into significant areas of new land which must be cleared and prepared for soya production. Side effects of this process include deforestation, the destruction of species and habitats, removal of natural vegetation and the loss of ecosystem functions and services. Not only does the natural vegetation protect and sustain biodiversity, it also plays a role in regulating climate and hydrological cycles’. 37

23

3.3

ANIMAL FEED PRODUCTION: LAND AND FERTILISER USE

As animal production systems intensify, more land is needed to grow high protein and high energy crops for their feed, and more mineral fertiliser is used to obtain a high yield from the crops. Intensive methods are leading to the decline of the sustainable use of crop residues for feeding livestock.

Land use The use of grain-feeding for livestock started in North America in the 1950s and is now common in much of East Asia, Latin America and West Asia as well as in all developed countries. It is also increasing rapidly in sub-Saharan Africa and South Asia. The cereal component (such as wheat, maize, barley) is about 60% of chicken feed and 60-80% of pig feed across most countries, including China, Brazil and Thailand.35 An estimated 33% of the world’s cropland is used to grow animal feed-crops. This is in addition to the estimated 26% of the world’s land area that is used for animal pasture. For some crops, such as maize (60%) and soya (97%), most of the world’s entire crop is used for animal feed. 5,35 Half the wheat and barley produced in the UK is used for feed.13 The FAO estimates that if livestock production increases as predicted, even more land will be taken over for feed-cropping. The share of cereals used for feed will increase still further as developing countries expand and intensify their animal production systems. Nearly 80% of the increased use of feed maize up to 2030 is expected to be in developing countries.35 This is very likely to create immense pressure on land resources and result in carbon dioxide losses from degraded soils, fossil fuel use for tillage and fertiliser production and nitrous oxide emissions from fertiliser use.

N fertiliser use Mineral fertiliser use requires large amounts of fossil fuel energy to manufacture and creates nitrous oxide emissions and nitrogen pollution in use (eutrophication, acidification, ozone layer damage). While most countries use natural gas to manufacture mineral fertiliser, the carbon dioxide emissions from China’s production are relatively higher because coal energy is typically used for fertiliser manufacture. The FAO estimates that globally 20-25% of the total mineral fertiliser is applied to feed-crops. In some countries the proportion used is very much higher and is typically over 50% in developed countries. 5

24

TABLE 8: Proportion of mineral fertiliser used for feed-crops (and pasture) Source Steinfeld et al, 2006, Table 3.3 (data from 2002 and 2003) 5 Proportion of total N fertiliser used for feed-crops and grassland for animal production, rather than for food crops for direct human consumption (* indicates countries where significant grassland fertiliser use)

UK

70 % *

Germany

62 % *

Canada

55 %

France

52 % *

USA

51 %

Spain

42 %

Brazil

40 %

Argentina

29 %

Mexico

20 %

Turkey

17 %

China

16 %

3.4

ANIMAL FEED PRODUCTION AND DESERTIFICATION OF PASTURES

Intensive animal production with its demand for feed-crops contributes to over-exploitation of grazing land and to desertification. Desertification is one of the most serious of global environmental challenges and one that often affects the poorest people. The demand for land for feed grain for intensivelyproduced animals is increasing the pressure on grazing land. Feed-cropping is taking over pasture land and this is expected to continue in many developing countries.5 Pasture land is already under pressure. According to the FAO, the world’s pastures already have their ‘backs against the wall’. Grazing is already moving into marginal areas where it has ‘reached the limit allowed by climate and soil.’5 Any expansion of grazing is likely to be into forests or other ecologically valuable areas.35 The loss of pasture land to feed-cropping is likely to lead to overgrazing of any remaining grazing areas, and hence to desertification. This is a particularly serious threat at a time of climate change. Already 73% of the world’s dry rangelands are degraded to some extent. 14 A study published in Nature commented in September 2007: ‘Arid ecosystems are among the most sensitive ecosystems to global climate change. High grazing pressure pushes arid ecosystems towards the edge of extinction. Increased aridity can then lead to desertification in a discontinuous way, where the possibility of recovery will be low’.38 According to the Millennium Ecosystem Assessment, desertification affects the livelihoods of more than 25% of the world’s population. 38

3.5

RESOURCE CONFLICTS DUE TO ANIMAL FEED PRODUCTION: CEREALS AND WATER

The current huge expansion in the size and intensity of animal production worldwide looks particularly unsustainable in the light of the probable effects of climate change, because it makes such heavy demands on land and water for growing feed-crops. The disproportionate and growing demand for cereals for use as animal feedstuffs is already contributing to the worldwide cereal price increases caused partly by drought and reduced harvests. This is perhaps one of the first indications of the resource conflicts due to intensive animal production that are likely to become more serious in the future. 25

The demand for feed-crops will increasingly come into competition with the demand for land and water for other purposes, including energy production (biofuels), forestry, aquaculture (demand for cereal for feeding fish) and the need to grow crops for human food. Livestock production will be a likely contributor to human conflict over water resources. The use of water for livestock production is projected to increase by 50% up to 2025. By that date, up 64% of the world’s population is likely to be living in water-stressed environments. In areas where water is used for irrigation, 15% of the water lost by evaporation and by transpiration (evaporation from plant pores) from plants can be attributed to feed crops.11 The FAO has concluded: ‘It is clear that feed production consumes large amounts of critically important water resources and competes with other usages and users’.11 In addition, the intensified land use for feed crops and grazing can only exacerbate the environmental effects of climate change. Intensive animal farming is a significant cause of deforestation, the over-use of arable soils leading to loss of soil organic matter, erosion and soil compaction and the loss of traditional hardy animal breeds as they are replaced with higher-yielding but less well-adapted western breeds.39 All these trends will only increase the damage caused to food production and the environment due to changes in climatic conditions such as more frequent drought, floods, storms and harvest failures. Although the detailed impact of future climate change on different world regions is still unclear, the intensive use of land and water resources for animal production may even become unviable in some regions of the world and is likely to add to existing environmental problems globally.

BOX 2: GHG overview: methane, nitrous oxide and carbon dioxide

GHG emissions from livestock farming do not follow the same mix of GHGs as in other sectors of the economy. Of the three main greenhouse gases emitted by all human activities globally, carbon dioxide (CO 2) accounts for around 77% of total anthropogenic GHG emissions, methane (CH4) for 15% and nitrous oxide (N2O) for 8%, in CO2 equivalents.4 CO2 emissions due to generation and use of fossil fuel energy contribute over half of the total, although deforestation is another important source of CO2 that is not related to fossil fuel energy use.40 GHGs due to animal production are divided fairly evenly between CO2, CH4 and N2O (38%, 31%, 31%). Of the 18% of total anthropogenic GHG emissions that can be attributed to livestock production, the three GHGs make approximately the same level of contribution (CO2 6.8%; CH4 5.5%; N2O 5.5%).5

Most of the CO2 emitted from animal production comes from livestock-related deforestation, not from fossil fuel use. CO2 from fossil fuel use makes up a relatively small part of the total livestock-related emissions. On the other hand, CO2 emissions due to deforestation and land use (eg: loss of CO2 stored in soil and vegetation) make up a relatively large proportion of all livestock-related emissions (see text and TABLES 4 and 7). Deforestation for animal production makes up nearly 8% of all human-induced CO2 emissions and 6% of total human-induced GHG emissions.5

26

BOX 3: FURTHER INFO BOX Absorption of nitrogen from food, fertilizer and manure A large part of the nitrogen that is applied to plants (in mineral fertiliser or manure) or eaten by animals in feed is not absorbed. Absorption is probably 59-60% for crops and less for animals. Global estimates for absorption of N (ie: protein) by animals are: pigs globally, 20%; poultry globally, 34%; dairy products in US, 40%; beef cattle in US, 5%.5 The remaining N in animal feed is excreted in urine and faeces and is either deposited on land by the animals or stored on farm and subsequently spread on land. The manure in the environment that is not absorbed by plants produces large amounts of N2O and ammonia (NH3). The demand from intensive animal production for high protein/high nitrogen animal feed and the production of feed-crops therefore contributes to N2O production (and pollution by ammonia).

Eutrophication (nutrient enrichment of ecosystems) The elements nitrogen (N) and phosphorus (P) are essential to plant (and animal) life and growth but excessive concentrations in ecosystems act as environmentally damaging pollutants. N and P are supplied in animal feed and excreted in manure and are also supplied in mineral fertiliser for plants. The N in fertiliser and manure that is not absorbed by crops causes nutrient enrichment (‘eutrophication’) of ecosystems, including lakes, rivers and seawater. Those organisms that can use high levels of nutrients flourish at the expense of others, altering the balance of species. In water, eutrophication causes large growths of algae that can kill other organisms because they use up the oxygen in respiration and when they decay and because they block out light. Algae can also be toxic to fish and cause large-scale fish kills in polluted water.

Role of ammonia in acidification (‘acid rain’) Ammonia (NH3) contributes to acidification when ammonia and oxygen in the atmosphere combine to form nitrogen dioxide (NO2). Nitrogen dioxide then combines with water and oxygen in the atmosphere to form nitric acid (HNO3) which can be deposited as ‘acid rain.’ Dissolved ammonium ions (NH4+) can also form nitric acid when deposited on soil. The path is: ammonia →nitrogen dioxide → nitric acid.

Production of nitrous oxide (N2O) from fertiliser or manure Plants use nitrogen in the form of nitrate (NO3-), which can be obtained directly from mineral fertiliser or from decomposition of manure. Organic N in faeces and urine (urea and uric acid for poultry) is converted to NH3 (ammonia) and NH4+ (ammonium ions), followed by ‘nitrification’ to nitrite (NO 2-) and nitrate (NO3-) in the presence of oxygen (ie aerobic conditions). If parts of the manure then become saturated or airless (anaerobic conditions) nitrates and nitrites are reduced (ie: loss of oxygen) to nitrous oxide (N2O) and ultimately to nitrogen gas (N2) which returns to the atmosphere (referred to as ‘de-nitrification’). The first stage of production of N2O is aerobic (ie: dry or open to air, oxygen present) and second stage is anaerobic (ie: wet or airless conditions, little oxygen present). The production of N2O from animal manure globally is several times greater than the production of N2O from use of N fertiliser on feed-crops.5

Methane and nitrous oxide emissions from manure Manure is the largest single source of livestock-related GHGs after deforestation. CH4 and N2O are produced from manure by that is collected and stored on farm by different methods. Slurry (liquid manure) produces more methane and dry manure produces more nitrous oxide. Hence attempts to reduce either CH4 or N2O by changes in manure management could result in increasing the other one. Apart from manure management, two thirds of total global manure-related emissions arise from nitrous oxide emitted after manure is deposited or spread on land.5 The problem is therefore one of excessive manure production.

27

BOX 3 CONTINUED: FURTHER INFORMATION BOX Production of methane and oxidation (breakdown) of methane in soils Methane is produced in lower layers of soil by anaerobic bacteria and atmospheric methane is assimilated into soil, in forests, grassland, tundra, heathlands and deserts. Soil bacteria can use up CH4 as a source of carbon in a process known as methane oxidation. Soils thus act as a methane sink amounting to millions of tonnes per year. If soil becomes waterlogged, the balance of bacteria can change to anaerobic methane-producing bacteria. Increased nitrogen concentration in soil (usually through human activity) inhibits methane oxidation. Hence it is necessary to avoid excess N deposition on soil to maintain soil as a methane sink.

4.0

DIET, FOOD PRODUCTION AND GHGS IN DEVELOPED COUNTRIES

Meat production is usually an inefficient way of producing human food except in marginal lands unsuitable for crops and only suitable for grazing. In modern animal production, at least some or all of the plant protein fed to animals could also be eaten by humans. Producing meat involves converting plant protein (fed to animals) at low efficiency to edible animal protein (meat). As the IPCC noted in 2001: ‘A shift from meat towards plant production for human food purposes, where feasible, could increase energy efficiency and decrease GHG emissions’. 20 Animal products have a high global warming potential per kg compared to most plant-based foods. There is now abundant evidence from recent studies in UK, Europe, US and Japan that meat and dairy production and consumption make very significant contributions to the GHGs of developed countries. These facts have implications for governmental GHG reduction strategies and targets and for the choices made by any individual consumer in order to reduce his or her carbon footprint. Diets high in animal products increase GHG emissions and increase an individual’s carbon footprint. Diets high in plant products save energy and reduce an individual’s carbon footprint .

4.1 THE CONTRIBUTION OF MEAT AND DAIRY PRODUCTION TO EUROPE’S GHGs A number of recent studies have shown that meat and dairy products are food choices with the highest global warming potential according to Life Cycle Assessment methods. The European Commission’s 2006 report on the Environmental Impacts of Products (EIPRO) found that in the EU25, all food production and consumption accounted for 31% of total emissions.7 Meat and dairy products accounted for 13.5% of total emissions, that is nearly half of all emissions relating to food. 8 In addition, red meat contributed 11% and poultry meat 7% to eutrophication (nutrient enrichment of ecosystems, see Further Info Box) in the EU25. Meat production and processing was put in the top five products for environmental impact and milk was put in the top 10.6 The 13.5% of total EU25 emissions from meat and dairy should be compared with an estimated 3% due to civil aviation in the EU15 in 2005.25 In the UK, the Food Climate Research Network has estimated that meat and dairy products contribute 8% of total GHG emissions, compared to only 2.5% for fruit and vegetables6, 8 (see TABLE 9). The 8% from meat and dairy should be compared with an estimated 6.5% contributed by UK aviation in 2005.41 A Netherlands study also found a high proportion of food GHGs are due to meat and dairy products. Meat and fish contribute 28.2% of all food-related emissions in the Netherlands; dairy contributes 22.9%;

28

potatoes, fruit and vegetables contribute 14.6%; and bread, pastry and flour contributes 13.3%. Accordingly, meat, fish and dairy contribute half of all Dutch food-related GHG emissions 6 (see FIGURE 2). TABLE 9: Relative contribution of meat & dairy and other food sources of GHGs in the UK Source: Garnett, 20078 FOOD CATEGORY

Contribution to total UK GHG emissions

Meat and dairy

8%

Fruit and vegetables

2.5 %

Alcoholic drinks

1.5 %

Food-related transport

2.5 %

Food manufacturing

2.2 %

Fertiliser manufacture

1%

A large majority of GHG emissions related to meat and dairy products (up to 96% in the UK) are the result of rearing the animals (ie: up to farm gate) rather than the result of food processing, transport, retailing and consumption.6 The animal production on the farm therefore has to be the main focus of GHG reduction strategies. As has been pointed out by the Food Climate Research Network, the true tally of GHG emissions due to meat and dairy products may be higher than has been calculated by straightforward Life Cycle Assessment studies because: ‘They do not …take into account some of the more complex issues, such as lost carbon sequestration potential (in the case of soya) or the opportunity cost of land take’. 6 Therefore the real global warming potential of meat and dairy production in Europe is probably even higher than that calculated by published studies so far if we include important indirect effects such as deforestation in South America to grow soya beans for animal feed. FIGURE 2: Relative contribution of products to Dutch food GHGs. Re-drawn from Garnett, 20078

Contribution of food types to total Dutch foodrelated GHGs

meat and fish 28.2%

other 21.0% bread & flour 13.3% fruit & vegetables 14.6%

4.2

dairy 22.9%

ENVIRONMENTAL IMPACT OF DIFFERENT ANIMAL-BASED FOODS

The global warming potential of different foods depends on the amount of fossil fuel energy consumed (for example in concentrate feed production) and the amount of methane and nitrous oxide produced by 29

enteric fermentation, manure and fertilisers, per unit of output. A unit of output could be 1kg of meat, milk or eggs. There is a considerable difference in the global warming potential per unit output between ruminant animals (beef cattle, dairy cows, sheep and goats) and non-ruminants (pigs and poultry).

4.2.1

Ruminant and non-ruminant animals

Ruminant animals, such as cattle and sheep living in extensive conditions and getting their main nutrition from grass, can be reared with relatively little input of energy, as happens throughout the world in traditional farming systems. One kilogram of beef produced on an intensive US beef feedlot has been estimated to have twice the environmental impact of 1kg of beef produced on pasture in Africa. 6 Grazing cattle and sheep also contribute to preserving the countryside and landscapes and they often provide livelihoods in regions that are unsuitable for arable farming. However, the fact that they can digest fibrous material such as grass means that they produce large quantities of methane from enteric fermentation. They deposit their dung on land (in developing countries this is an essential resource for fertiliser and often for fuel) where it emits nitrous oxide. Cattle and sheep normally give birth to young only once a year and also grow to their slaughter weight relatively slowly. When slaughtered, their carcases yield a lower proportion of edible meat per carcase than is the case for pigs and poultry. Pigs and poultry reproduce rapidly and grow to their slaughter weight very fast, particularly in factory farming conditions. As a result, the rearing of cattle and sheep produces more GHG emissions per unit of output than rearing pigs and poultry. Pigs and poultry, on the other hand, are fed on specialised feedcrops (such as cereals and soya) which require large resources of land and water and the use of fertilisers and pesticides. Studies of production and consumption in the UK6, 26, 42 have shown that the largest contribution to total GHG emissions comes from beef production, followed by milk, pig meat, poultry meat, sheep meat and eggs (TABLE 8). Sheep meat production gives the largest GHG emissions per kg of meat but relatively little is consumed.

TABLE 10: GHG emissions due to production and consumption of different animal products in the UK Source: Garnett, 20076 (based on GHG calculations of Williams, Audsley and Sandars, 2006 26)

From UK production of:

% contribution to total UK GHG

GHG emissions (kg CO2

emissions based on 2006

equivalent) per kg of meat,

consumption

eggs or milk

Beef

2.32 %

15.8

Pig meat

1.12 %

6.4

Poultry meat

1.10 %

4.6

Sheep meat

0.85 %

17.4

Eggs

0.40 %

5.5

Milk

1.89 %

10.6 [1]

Total to farm gate

7.69 %

Total after farm gate

0.35 %

Total pre + post- farm gate

8.03 %

[1] Given for milk dry matter

30

Different animal products therefore vary in the levels of GHGs emitted, but in nearly every case animal production has a higher global warming potential than the production of plant-based foods. An exception is the production of hothouse vegetables such as tomatoes, which also have a high GWP. A review of the environmental impact of UK food production conducted for Defra at the Manchester Business School and published in 2006 summarised the situation as: ‘Energy inputs [are] high for all meats’ and that ‘Legumes are a more energy-efficient way of providing edible protein than red meat’. 43

4.2.2

Organic and free-range farming

The difference in GHG emissions between ruminant and non-ruminant animals is true, even when cattle and sheep are reared in organic farming conditions. In organic farming, mineral fertiliser is not used and the use of concentrate feed is relatively low, which reduces the GHG emissions from these sources. Organic farming uses considerably less energy than non-organic farming44 (TABLE 11) and UK studies have found that organic production of pig meat and sheep meat emits lower levels of GHGs per kg of meat than non-organic pig and sheep production.26 The percentage of organic production in the UK is currently not more than 1% for any animal product.6 There could therefore be considerable energy savings and reduction in GHG emissions from pigs and sheep (and possibly from beef and dairy production as well, although the situation is less clear) if the organic sector were greatly expanded. There is recent evidence from the University of Michigan and Michigan State University, examining organic yields and resource use, that ‘organic agriculture has the potential to contribute quite substantially to the global food supply, while reducing the detrimental environmental impacts of conventional agriculture’. 45 When meat chickens are reared in the best free-range and organic farming systems, the birds have a lifetime twice as long as factory farmed chickens and a very much better quality of life, with access to an outdoor range, fresh air and exercise. But because the birds often live twice as long (eating and excreting) before they are slaughtered, organic and free-range chicken farming produces somewhat higher GHG emissions per kg of chicken meat than does factory farming of chickens. However, the difference between the GWP of factory farmed poultry meat and free-range poultry meat is very small compared to the much higher GWP difference between any poultry meat and beef or sheep meat. 26

TABLE 11: Change in energy use for selected products as a result of organic farming, compared to non-organic farming Source: Soil Association, 2007 44 PRODUCT

% change in energy use in organic farming, compared to non-organic farming

Milk

38% less

Beef

35% less

Lamb

20% less

Pig meat

13% less

Eggs

14% more

Chicken meat

32% more

Wheat

29% less

Oilseed rape

25% less

31

4.3

ENERGY USE & GLOBAL WARMING POTENTIAL ASSOCIATED WITH CHOICE OF DIET

Studies in Europe, the US and Japan have shown that increasing the quantity of meat in a person’s diet increases the global warming potential and decreases the energy efficiency of that diet. A more carefully chosen diet that is low in meat and is seasonal and local can greatly reduce an individual’s carbon footprint – and can be a more important environmental choice than the means of transport. Research in Sweden has compared various nutritionally-balanced meals consisting of ‘domestic’ and ‘non-domestic’ (ie: imported) food items. It was found that a locally-produced vegetarian meal had only one-ninth the GWP of a meal that contained pork and a non-domestic food item. The ‘domestic’ vegetarian meal produced the lowest level of GHG emissions for the highest level of nutrients (protein, calories and beta-carotene) followed by the ‘domestic’ meal containing pork. 46 Calculations on a wide range of foods in Sweden show big differences between the energy input needed to produce portions of different food items. Portions of meat and animal products are nearly always more energy-demanding than plant-based products (pulses, grains, pasta, vegetables, fruit) and imported foods usually consume more energy than domestically-produced foods (TABLE 12). The highest energy input is required by beef, cod and farmed salmon. The energy input for domestic pork is over three times the energy input for imported soya beans.47 (Soya is a significant component of commercial pig feed, illustrating the inefficiency of our animal food system.)

TABLE 12: Energy required per portion of food item Source: Carlsson-Kanyama, 2003 47 Food item, provenance and preparation ‘domestic’ =

Energy per portion consumed (M

originating from within the country (Sweden)

joules per portion)

ANIMAL PRODUCTS Domestic beef, fresh, cooked

8.8

Domestic lamb, fresh, cooked

5.4

Domestic chicken, fresh, cooked

4.4

Domestic pork, fresh, cooked

5.0

Domestic mackerel (caught), cooked

4.7

Domestic farmed salmon, cooked

11.0

Domestic cod (caught), cooked

13.0

Yoghurt, domestic, small pot

2.2

Eggs, domestic, cooked

1.8

Milk, domestic (full fat)

1.2

Cheese, domestic

0.9

Cheese imported from southern Europe

1.0

NON-ANIMAL PRODUCTS Brown beans, domestic, cooked

1.7

Peas, domestic, cooked

0.95

Soya beans, imported, cooked

1.51

Potatoes, domestic, cooked

0.91

Carrots, fresh, domestic

0.19

White cabbage, fresh, domestic

0.26

Broccoli, imported frozen, cooked

1.2

Tomatoes, domestic, glasshouse

4.6

32

TABLE 12 CONTINUED: Energy required per portion of food item. Food item, provenance and preparation ‘domestic’ =

Energy per portion consumed (M

originating from within the country (Sweden)

joules per portion)

Muesli with sun-dried raisins, domestic

0.69

Oat porridge, domestic, cooked

0.69

Rice, imported, cooked

1.1

Pasta, domestic, cooked

1.2

Pasta imported from southern Europe, cooked

1.3

Couscous imported from central Europe, cooked

1.1

Bread, fresh, from local bakery

0.44

Bread, fresh, from non-local bakery

0.48

Apples, domestic, fresh

0.44

Cherries, domestic, fresh

0.63

Raspberries imported from central Europe

0.9

Strawberries, domestic

0.77

Strawberries imported from southern Europe

1.1

Research from the University of Chicago has shown similar results by looking at a several variations on the average American diet. Variations included higher meat, higher fish, higher poultry or vegetarian (including dairy and eggs) diets. Food items differ widely in their energy efficiency, that is the quantity of food energy (calories) they provide divided by the quantity of energy needed to produce them. The researchers found that increasing the animal-product component of any diet decreases the energy efficiency of the diet and increases the methane and nitrous oxide emissions from its production. 48 The results for the US showed that the energy efficiency of vegetable foods is very much greater than energy efficiency of animal products; for example, soya is 65 times as energy efficient as grain-fed beef and 73 times as energy efficient as farmed salmon, per unit of food energy (calories) consumed. 48 The study concludes that the differences in energy efficiency between the average American diet and an entirely plant-based diet, with the same protein and calorific content, constitutes emissions of 701kg CO2 per person per year, roughly a third of the GHG costs of a person’s use of a standard car for personal transportation. Considering the total GHG impact of different diets, the scientists comment: ‘To place the planetary consequences of dietary choices in a broader context, note that at mean US calorific efficiency, it only requires a dietar y intake from animal products of [approximately] 20%, well below the national average, 27.7%, to increase one’s GHG footprint by an amount similar to the difference between an ultra-efficient hybrid (Prius) and an average sedan (Camry). For a person consuming a red meat diet at [approximately] 35% of calories from animal sources, the added GHG burden above that of a plant eater equals the difference between driving a Camry and an SUV.’

48

A study of beef production in Japan published in 2007 showed that the production of one beef calf emitted 4.5 tonnes of GHG (CO2 equivalent) and required over 16 giga joules of fossil fuel energy. 31 According to a calculation in New Scientist magazine, this means that the production of 1kg of Japanese beef (excluding the farm infrastructure and transport) is equivalent to the amount of CO2 emitted by the average European car driven for 250km, and burns enough energy to run a low-wattage light bulb for 20 days.49

33

A 2007 calculation based on Australia’s National Greenhouse Gas Inventory estimated that average beef consumption in the Australian diet is equivalent to1.45 tonnes of greenhouse gas per person per year. This is more than the difference between a year’s emissions from driving a standard car compared to an energy efficient hybrid car. 50 The health risks of a diet high in beef burgers and other fast foods are already well known. Public health experts also believe that there would be many health benefits to people in developed countries in adopting a diet much lower in meat and dairy products and higher in plant-based food.2, 51 Another major advantage of a reduction in meat consumption is that it is one of the quickest, easiest and least costly steps that any individual in a developed country can take to reduce his or her carbon footprint.

BOX 4: Projected GHG increases if no action is taken Agricultural N2O emissions are projected to increase by up to 35-60% by 2030 due to increased manure production and N fertiliser use. If CH4 emissions grow in proportion to animal numbers, livestock-related methane production is expected to increase by 60% to 2030 (enteric fermentation and manure management).19 Some developing regions will have very high increases: East Asia, including China and India, is predicted to increase emissions from enteric fermentation by 153% and manure management by 86% between 1990 and 2020.19 Africa, Latin America (mainly Brazil and Argentin a) and the Middle East are predicted to increase nitrous oxide emissions (mainly due to animal manure) by over 100%.34 Increases in pig and poultry production globally are expected to contribute largely to these rises.34 Developed countries in North America and the Pacific (mainly Australia and New Zealand) are also likely to increase emissions by around one-fifth19 both largely due to increased quantities of animal manure. Western Europe is the only region where emissions are falling and predicted to continue to decrease to 2020.19 This is attributed to a reduction in animal numbers and environmental regulation. The very large increases in developing regions, which are unlikely to be easily controlled, make it all the more essential that emissions are cut drastically in developed countries in order to reduce the global total.

34

PART 2: BALANCING NEEDS & SOLUTIONS 5.0

HOW TO REDUCE LIVESTOCK-RELATED GHGS GLOBALLY

Livestock-related GHG emissions are now recognised to be a significant contribution to global warming. It is also agreed that large reductions in livestock-related GHGs are needed. According to the FAO, the environmental impact of livestock production must be cut by at least half.14 In spite of these concerns, most of the mitigation proposals put forward aim at relatively small adjustments and have so far avoided reassessing the goals and structure of the global animal production industry. The essential questions – what level of animal products are needed, and what is the most environmentally and animal-friendly way to produce them – have not yet been asked. Various strategies and technical options have been put forward to cut emissions while maintaining or increasing current levels production of meat and milk. These range from proposed changes to feed composition to manipulation of animals’ digestive systems, to intensifying animal production. Compassion in World Farming finds these strategies unconvincing and inadequate to the task. Most of them are hardly realistic or cost effective in the context of practice on farm, especially among small farmers. Others are unacceptable on ethical or political grounds. Studies have in any case shown that the proposed mitigation routes could only succeed in reducing emissions by up to 20%2 very much less than is needed. Most importantly, none of the proposed management changes could be made effective in the short time scale that is essential to prevent further GHG emissions and limit future global warming. The FAO has pointed out that it is essential that the animal production industry pays the external costs of their activities (such as climate change and other environmental damage).14 Compassion in World Farming agrees with the Stern Review that: ‘The first essential element of carbon change policy is carbon pricing’.52 This policy must now be applied to the production and consumption of meat and other animal products.

5.1

ASSESSMENT OF SOME MITIGATION STRATEGIES OFFERED BY EXPERTS

Mitigation refers to measures that could limit the eventual global temperature rise by reducing current and future GHG emissions. Measures relating to livestock-related GHGs by experts such as the FAO and IPCC 3, 21 include the following:

1. Reversal of deforestation and land degradation due to over-cultivation or over-grazing: these include incentives for conservation and re-forestation in the Amazon and other tropical areas; restoring organic carbon in soils, conservation tillage (ie: leaving over 30% of crop residues on the soil surface, minimising disturbance of soil by ploughing, etc.), organic farming, reversing soil carbon losses from degraded pastures by better grazing practices, including optimising grazing animal numbers (ie: to benefit from manure and vegetation management while avoiding overgrazing). 2. Better management of manure and fertilizer; better use of anaerobic digesters to produce methane for fuel from slurries; reduction of energy use in animal housing and use of ‘green’ energy sources. 3. Changes to feed or chemical treatment of animals to reduce both production of methane in digestion and losses of nitrogen (including nitrous oxide) from manure: these include optimising the nitrogen 35

content of feed to increase absorption and reduce nitrogen excretion; using higher quality and less fibrous feed to reduce production of methane in the gut; dietary additives, including antibiotics, to reduce methane production; vaccination of animals against methane-producing gut bacteria. Better targeting of fertiliser use and manure spreading are obviously good practice and arguably should already be normal farming practice in developed countries. Greener energy sources, including the use of waste organic matter, are also obviously necessary. But the dietary and chemical treatments proposed for animal management are unlikely to be feasible, either technically or financially, for most farmers. Some of the strategies are likely to be self-defeating. Feeding cattle a diet that is lower in fibrous material and higher in grain does reduce the amount of methane the animals produce by their digestive processes because feed that is less fibrous requires less fermentation in the rumen. However, this would require even greater production of specialised feedstuffs, which is already one of the main causes of livestock GHG emissions. There would also be other environmental damage such as overuse of land and water and nitrogen pollution from mineral fertiliser. From the point of view of the cattle the strategy is also very questionable, since cattle are designed to digest fibrous food and suffer (for example from acidosis) if they are fed too high a proportion of concentrate feed. Organic farming cattle standards, for example, require that at least 60% of the dry matter in cattle diet is in the form of fibrous foods (grass, silage, etc.) for this reason.53 High quality animal feed is out of the reach of poor communities and would compete with the much greater need of producing food for people, especially in the context of harvest failures due to climate change. Feedcrops are also coming into competition with the need to use land for biofuels. In the assessment of Compassion in World Farming, whilst better management of land, manure and fertilisers are useful and necessary, none of the strategies offered has the realistic potential to achieve the large and rapid reduction in global GHG emissions that is needed. According to a 2007 report from an international group of scientists, ‘available technologies for reduction of emissions from livestock production, applied universally at realistic costs, would reduce non-carbon dioxide emissions by less than 20%’.2

5.2

WHY INTENSIVE ANIMAL PRODUCTION IS THE WRONG ANSWER

Most of the GHG emissions from livestock production, even in developed countries where concentrate feed, fertiliser and machinery are used, arise from the natural biological processes (ie: methane and nitrous oxide from digestion and manure). They are thus to a great extent a ‘given’ for that animal. For this reason, one strategy recommended by some agricultural scientists is to increase the yield per individual animal and thus reduce the GHG emissions per kg of product (meat, milk, eggs). This essentially means working the animals harder and getting more product out of them during their lifetimes, either by reducing their lifetimes or by increasing their output, or both. This could be done by young calves, piglets, chickens and lambs being grown to their slaughter weight in a shorter time and being bred to have more muscle, cows producing more milk per year, breeding animals producing more young and with a reduced turnaround time between giving birth. The suggestion has even been made that more dairy cows should be injected with the growth hormone BST (bovine somatotrophin) to increase milk production;19 BST has been banned in the EU because of its risks to animal welfare, although it is quite commonly used in US dairy production.

36

Compassion in World Farming considers that the intensification of animal production would be deeply flawed response to global warming, from the practical, environmental and animal welfare points of view. It would also be ethically and politically unacceptable to consumers in developed countries, where concern about the welfare and environmental effects of farming, and the demand for free-range and organic animal products, is increasing fast. The latest Eurobarometer survey found that 58% of EU25 citizens in 2005 considered the welfare of hens in Europe to be ‘fairly bad’ or ‘very bad’ and 38% stated that they chose to buy eggs from freerange or outdoor systems (50% or more in seven countries, including Germany, Sweden, Denmark and UK). 42% said that the welfare of laying hens and meat chickens needed to be improved the most. In the same survey, 44% of EU25 citizens considered the welfare of pigs to be ‘fairly bad’ or ‘very bad’. 54 The large majority of laying hens, meat chickens and pigs in the EU25 are kept in intensive systems and the survey shows that a significant proportion of public opinion is unhappy about this production method. Many people in developing countries may well take the same view. Further intensification of animal production would almost certainly mean rearing more pigs and poultry (non-ruminants), probably in industrial conditions, and relatively fewer cattle and sheep (ruminants). Exchanging pasture-based animal farming for an expansion of pig and chicken factory farms would be a very unpopular choice in many developed countries. Further, there is no reason to think that this unpopular strategy would deliver a rapid and adequate reduction in GHG emissions. In developed countries, where many believe intensification of animal production has already gone too far, it is unrealistic to suppose that a further increase in yield per animal could take place rapidly enough and be large enough to meet climate targets.

Studies of dairy production have shown that the relationship between high yield, intake of concentrate feed and cow lifetime is far from simple and is unlikely to be easy to optimise to create a really significant reduction in GHG emissions.27, 55 Chickens, pigs and dairy cows are already very high-yielding and in some cases this has already led to health problems as the animals are pushed to their physiological limits in the drive to increase productivity; lameness and heart disease are common among fast-growing meat chickens, breeding pigs increasingly suffer from lameness and high-yielding dairy cows are more likely to suffer from lameness, mastitis and infertility. 56-60 Conversely, pigs and poultry in organic and free-range systems are less stressed and generally somewhat less high-yielding than in factory farm pig and poultry production. Organic pig meat production has a lower global warming potential per kg than does intensive pig meat production and the GHG emissions for free-range poultry meat are only slightly higher than for factory farmed poultry meat.26 Organic farmers, as well as scientific studies55 and the IPCC 4th Assessment 19 point out that increasing yield per animal can be counter-productive if it means that more replacement animals have to be reared because breeding animals are worn out sooner. On high-yielding dairy farms, the cows are replaced more frequently26 as a result of infertility and ill-health. During the time that a replacement heifer is being reared (about two years to first lactation) she is eating, excreting and emitting CH4 from enteric fermentation without producing milk, therefore reducing the overall production per animal and increasing the GHG emissions of the herd as a whole.55

37

Intensification and the resultant stress on the animals are also regarded as significant factors in fastspreading infections such as porcine reproductive and respiratory syndrome (PRRS) and highly pathogenic avian influenza (HPAI). Such infections damage productivity and cause large financial burdens to the industry and often to taxpayers in costs of disease control and monitoring. 61, 62 Intensification of animal farming is a bankrupt strategy from the point of view of halting climate change and from environmental and animal welfare perspectives. Compassion in World Farming is disappointed that some agricultural scientists are approaching the livestock-global warming conundrum by calling for ‘more of the same’, rather than looking afresh at the whole issue of how best our society should rear animals for food.

5.3

WHY REDUCTION IN ANIMAL PRODUCTION IS THE MOST EFFECTIVE SOLUTION

Reduction in the size of the livestock industry in developed countries is the simplest, quickest and probably the only effective method of cutting GHGs from animal production to the extent that is necessary to prevent the future increase of global warming. Evidence already exists from Europe that reducing meat consumption and animal numbers reduces GHG emissions. The IPCC’s 4 th mitigation draft report on agriculture notes that Western Europe is the only world region where emissions are falling and are predicted to continue to decrease up to 2020. This decrease has occurred in large part because of a reduction in the size of the animal production industry in the EU, partly as a result of environmental regulation designed to reduce pollution. A 2001 study of ways to reduce GHG emissions from meat production in Belgium from the Federal Office of Scientific, Technical and Cultural Affairs concluded that reducing meat consumption ‘would have a significant impact on the global GHG emissions’.28 According to the report, all studies show that a reduction in livestock numbers is always the most efficient measure to reduce GHG emissions. The study calculated that a 10% reduction in livestock numbers in the country would reduce annual GHG emissions by 0.242 million tonnes CO2 equivalent.28 Recent research from the public health departments of the Australian National University, Cambridge University, The London School of Hygiene and the University of Chile has confirmed the essential role of reducing meat consumption in high-income, developed countries in order to reduce GHG emissions. Merely to prevent an increase in GHG from the livestock production sector, the researchers calculate that an overall cut of 10% in global meat consumption is required, limiting consumption to 90g per person per day. 2 The target consumption of 90g per person per day would be equal to a reduction in average meat consumption in rich countries of between 55% and 64%. For poorer and developing countries, where average per capita meat consumption is one-tenth of that in developed countries, the target would allow continued growth in consumption.2 These public health scientists consider that this level of meat reduction would offer ‘important gains to health’ for people who currently consume more than the 90g per day. The benefits would include a likely reduction in risk of colorectal cancer, breast cancer and heart disease, as well as the risk of becoming overweight or obese. The likely reductions in heart disease would be mainly due to reducing the consumption of saturated fat in meat.2

38

TABLE 13: Why factory farming is not a solution

ENVIRONMENTAL IMPACTS OF

ANIMAL WELFARE IMPACTS

FACTORY FARMING

OF FACTORY FARMING

Deforestation for animal feed production

Close confinement systems (cages, crates) or

Unsustainable pressure on land for production

lifetime confinement in indoor sheds

of high protein/high energy animal feed

Discomfort and injuries caused by inappropriate

Pesticide, herbicide and fertiliser manufacture

flooring and housing

and use for feed production

Restriction or prevention of normal exercise and

Unsustainable use of water for feed-crops,

most of natural foraging or exploratory behaviour

including groundwater extraction

Restriction or prevention of natural maternal

Pollution of soil, water and air by nitrogen and

nesting behaviour

phosphorus from fertiliser used for feed-crops

Lack of daylight or fresh air and poor air quality in

and from manure

animal sheds

Land degradation (reduced fertility, soil

Social stress and injuries caused by overcrowding

compaction, increased salinity, desertification)

Health problems caused by extreme selective

Loss of biodiversity due to eutrophication,

breeding and management for fast growth and

acidification, pesticides and herbicides

high productivity

Worldwide reduction of genetic diversity of

Reduced lifetime (longevity) of breeding animals

livestock and loss of traditional breeds

(dairy cows, breeding sows)

Species extinctions due to livestock-related

Fast-spreading infections encouraged by crowding

habitat destruction (especially feed-cropping)

and stress in intensive conditions

There is therefore abundant evidence that reducing meat production and consumption in developed, high-income countries has a number of benefits for society, besides the main goal of limiting future global warming. These benefits are very wide-ranging and include: Reducing the adverse environmental impacts of intensive animal farming Reducing the adverse animal welfare impacts of intensive farming Providing a market for higher-welfare meat, milk and eggs Improving public health through dietary changes and reducing medical costs Protecting biodiversity and landscape Reducing the economic costs of livestock diseases (Foot and Mouth Disease, Avian Influenza)

5.4

OPPORTUNITIES AND BENEFITS OF A DOWNSIZED ANIMAL PRODUCTION INDUSTRY

Reduction in the size of the animal production industry and in the consumption of meat and milk products would open new opportunities for both farmers and consumers. In the present culture of high consumption of animal products, many consumers who would prefer to buy high-welfare free-range or organic meat or milk cannot afford to do so. Similarly, farmers who would prefer to farm free-range or organically say that they cannot obtain the necessary price premium from retailers to enable them to do so. In a regime of lower production and consumption of animal products, society would consume less but consume higher quality, meat and milk. We would buy a lower volume of products but pay more per unit

39

consumed. The price difference would probably be similar to the current premium for best quality freerange and organic products. This would support the livelihoods of farmers to the same level as, or better than, the current high-production regime. It would empower farmers to produce fewer animals but to rear them to the same high welfare and environmental standards as the best free-range farms achieve today. It would revolutionise animal welfare standards and see the end of factory farming.

6.0

HOW MUCH DO WE NEED TO REDUCE ANIMAL PRODUCTION?

We have seen that a reduction in the level of animal production and the consumption of animal products would achieve very large gains in limiting climate change, protecting the environment and improving public health. This section examines the magnitude of each of these benefits in order to help determine the level of reduction in animal production that is required. Scientific evidence shows that if nothing is done to reduce emissions, the level of GHGs in the atmosphere could be three times the pre-industrial levels by the end of this century and, that this could lead to a future rise in temperature of 5ºC. Five degrees is the difference between the global temperature during the last ice age and the current global temperature, and therefore could have unknown and massive effects on the world in the next century. 63 Because of past GHG emissions, a rise of 1ºC is already inevitable. The EU and the UK are aiming to limit the eventual future temperature rise to 2ºC. In order to achieve this, the GHG level in the atmosphere needs to be stabilised at 450 parts per million (ppm) CO2 equivalent. This would require, according to the conclusions of the Stern Review, global emissions in 2050 being 70% below current levels.64 EU Heads of Government have agreed a European target of 20-30% reduction compared to 1990 levels by 2020.23 The countries of the UK (England, Scotland, Wales and Northern Ireland) are committed to a target of a 60% reduction in emissions compared to 1990 levels by 2050 and a reduction of around 30% compared to 1990 levels by 2020.23 (1990 levels for the UK are slightly higher than current levels. The UK has reduced overall GHG emissions since 1990 but looks set to miss its domestic target for carbon dioxide reduction.23) Recent scientific research suggests that a 60% target is not nearly enough to limit global warming to 2ºC. The Tyndall Centre for Climate Change has argued that UK cuts of up to 70% by 2030 and 90% by 2050 are required to stabilise atmospheric GHG levels at 450 ppm. A 2007 report by the House of Commons Environmental Audit Committee has criticised the government target of 60% cuts as too low and stated that it should be strengthened to take current science into account.24 US scientists similarly argue that the US needs to cut emissions down to at least 80% below 2000 levels by 2050 in order to achieve the limit of 450 ppm.24 As the Stern Review pointed out: ‘Climate change is global in its causes and consequences, and international collective action will be critical in driving an effective, efficient and equitable response on the scale required’.64 The livestock-related emissions in any one country or region affect the whole world’s climate. Real cuts in livestock-related GHG emissions by high-income countries would therefore reduce the total of global emissions and benefit the whole world. This is particularly important because poor countries are those most likely to be damaged by global warming.64

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6.1

MEETING GHG REDUCTION TARGETS

Current science suggests that the UK and other developed countries need to cut GHG emissions by well over half by 2050. It is possible that a 90% cut will be needed. These targets require immediate action if they are to be achieved.

The targets of 60% cuts by 2050 and 30% by 2020 are likely to become statutory in the UK and the rest of the European Union. Compassion in World Farming believes that the livestock industry must take its share of these cuts by reducing livestock production in line with the targets. We have seen that a reduction in animal production is the only rapid method to reduce GHG emissions from this sector. In line with GHG emission reduction targets, which may need to be raised in view of new scientific evidence, Compassion in World Farming believes that the European Union and other developed countries should reduce production and consumption of meat and milk to at least 60% below current levels by 2050 and to one third below current levels over the next decade (by 2020).

6.1.1

Meat production in developing countries

The meat reduction target proposed would initially apply only to developed, high-income countries, where consumption is currently very high and there is the potential for substantial cuts without detriment to either consumers or farmers. It leaves at least half of global emissions that come from animal production in developing countries untouched. As examples, the per capita meat supply in China is already nearly 80% of that in the UK1 and Brazil has a very large export trade in animal products. These countries may need to re-assess their production levels in future, when their domestic nutritional needs have been met. Meanwhile, in both developed and developing countries all feasible mitigation measures such as reforestation, increasing soil fertility, reduction and better targeting of fertiliser use, minimisation of transport, reduction in fossil fuel energy use, use of green energy and better management of wastes should be pursued as rapidly as possible.

6.2

ADDITIONAL TARGETS FOR REDUCING ANIMAL PRODUCTION

There are additional important reasons why we should plan for a reduction in livestock production and consumption. These are related to human health (becoming overweight or obese) and to the protection of biodiversity (globally and on farmland).

6.2.1 Meeting targets to improve human health The current epidemic of excess weight and obesity in developed countries (and among higher-income people in developing countries) has a number of causes, but a substantial contributor is the overconsumption of animal products (meat and dairy) and under-consumption of vegetables and fruits. According to a World Health Organization (WHO) paper on social inequalities and food-related ill-health: ‘An energy-dense diet high in saturated fat and low in foods of plant origin, together with a sedentary lifestyle, is the major cause of the pan-European epidemic in obesity and becoming overweight, with

41

increased risk of non-communicable diseases including cardiovascular diseases, certain cancers and diabetes’.65 The WHO’s European Anti-Obesity Charter of 2006 reported that 50% of Europe’s adults and 20% of children are overweight. 16.5% of adults and 7% of children are classified as obese.10 Over 20% of either boy or girl children (or both) are overweight in the following countries of the EU15: Spain, Greece, Portugal, England, Belgium, Italy, France, Austria and Sweden. More than a million deaths annually can be attributed to being overweight. Adult obesity and excess weight is responsible for up to 6% of the entire health care costs in the European region.10 In the UK, a government target to reduce adult obesity to 6% of men and 8% of women by 2005 has completely failed according to the 2007 Wanless report on health. In 2005, 23% of men and 25% of women were classified as obese.66 The health costs of obesity were estimated at up to GBP 3.7 million (USD 1.9 million) in 2002 and have certainly increased since then. The National Audit Office has calculated the potential gains from reducing this problem; one million fewer obese people in England could mean around 15,000 fewer people with coronary heart disease, 34,000 fewer people developing Type 2 diabetes and 99,000 fewer people with high blood pressure. 66 However, given current diets, the present situation looks difficult to change. While the UK government recommends consumption of five portions of fresh fruit and vegetables per person per day, only 28% of adults and 17% of children meet this target.66 In view of this situation, it is clear than any improvement in diet that could reduce obesity and excess weight would bring enormous benefits to individuals and cost savings to society. Evidence from the US suggests very considerable overproduction and over-consumption of food, including animal-based foods. Total daily calorie consumption per person per day (including wastage) in the US is estimated at 80% more than the required daily calorie intake.48 Recent estimates from public health experts in three countries suggest that a reduction in meat consumption in developed countries from the current 200-250 grams (g) per person per day to 90g per person per day (ie: a reduction of around 60%) would reduce excess weight and obesity and offer several other health benefits. 2 In late 2007 the World Cancer Research Fund and the American Institute for Cancer Research jointly published a report on nutrition and cancer prevention, which reviewed all relevant research and made a series of recommendations for both public health goals and personal actions on diet. The report cited both red meat (i.e. meat from cattle, pigs, sheep and goats) and processed meat (meats preserved by salting, smoking, curing or the addition of preservatives, such as ham, salami, bacon and sausages) as “a convincing cause of colorectal cancer” and asserted that there is limited evidence linking both to a range of other cancers, such as pancreatic cancer. 67 Although milk may be a “probable” protector against colorectal cancer, the report stated that there is limited evidence suggesting that both milk and dairy products are a cause of prostate cancer and that cheese is a cause of colorectal cancer. Diets high in calcium are a probable cause of prostate cancer. 68 The report cites “a limited amount of fairly consistent evidence” suggesting that animal fats are a cause of colorectal cancer. 69

A study from the US National Institutes of Health, published in late 2007, showed that those who eat a lot of red and processed meat have a 20% greater risk of developing colorectal cancer and a 16% increased risk for lung cancer. This study also showed statistically elevated risks for oesophageal and liver cancers.70

42

The World Cancer Research Fund report recommends a public health goal of consumption of no more than 300g red meat a week, with a personal goal of less than 500g a week, “very little if any to be processed”. 71 It recommends a diet composed mostly of “foods of plant origin”, with a public health goal of 600g non-starchy vegetables and fruit daily and a personal recommendation of at least 400g daily. In addition the report recommends consumption of relatively unprocessed cereals and pulses with every meal. 71 The report states that obesity and overweight increase risk of some cancers, but also risk of other conditions such as stroke, type 2 diabetes and coronary heart disease.71

These strong recommendations, based on the best global scientific studies, add strength to arguments for a reduction in livestock production and consumption.

In order to eliminate the epidemic of obesity by mid-century, and reduce current rates of certain heart conditions and cancers, Compassion in World Farming believes that the European Union and other developed countries need urgent targets to reduce meat and dairy consumption to somewhat under half of current levels - a reduction of around 60%.

6.2.2

Meeting targets to protect and enhance biodiversity

Animal production-induced damage to wildlife habitats is one of the major threats to biodiversity globally. According to the FAO: ‘livestock play an important role in the current biodiversity crisis, as they contribute directly or indirectly to all these drivers of biodiversity loss, at the local and global level’ through habitat change, climate change, overexploitation and pollution and ‘over 70% of globally threatened birds are said to be impacted by agricultural activities’.72 Livestock are one of the major drivers of habitat change, whether for feed production or direct livestock production and contribute directly by over-grazing and over-stocking to deforestation and desertification. The FAO notes that projected land use changes up to 2010 are likely to increase deforestation still further in protected areas of central and South America. These threatened countries and areas include Guatemala (mainly Laguna del Tigre national park), the eastern Venezuelan Amazon, the Colombian national park Sierra de la Macarena and the Cuyabeno reserve in northeastern Ecuador. The majority of this projected deforestation is linked to providing pasture for animal production.72 Research by conservation organisations has also highlighted the threat from the expansion of animal production. WWF reports that livestock production is a current threat to 306 of 825 identified terrestrial eco-regions. Conservation International reports that 23 of 35 identified global biodiversity loss hotspots are ‘affected by livestock production’. The World Conservation Union (IUCN) Red List of Threatened Species shows that ‘most of these are suffering habitat loss where livestock production is a factor’.14 On the positive side, it has been shown that biodiversity is protected by organic farming methods, where the density of livestock is relatively low and mineral fertilisers and pesticides are not permitted. A survey of the European evidence published in 2005 showed that organic farming has major benefits for biodiversity: organic farms have on average 50% more plant species than intensive farms, twice as many skylarks, 40% more birds overall, twice as many butterflies, 60% more arthropods that comprise bird food, five times as many spiders overall and twice as many spider species.73 The most serious threat to present and future biodiversity is climate change. A rise of 2ºC in global temperatures could result in the extinction of 15% to 40% of land species and the destruction of coral 43

reefs and tropical mountain habitats. Up to 60% of South African mammal species could be lost. A rise of 3ºC or more, which is likely if GHG reductions are not made urgently enough, could see the extinction of up to half of all land species. Biodiversity ‘hotspots’ could lose thousands of species. 74 This evidence emphasises again that it is urgent to reduce the global warming potential of animal production in line with current or future GHG reduction targets for other sectors of the economy. Reduction of livestock production and consumption is the only quick and effective way to achieve these reductions.

In order to meet targets to protect biodiversity, Compassion in World Farming believes that the production and consumption of meat and dairy products in developed countries should be reduced to 60% below current levels, or further, by 2050 and should be reduced to one third below current levels by 2020.

7.0

HOW COULD MEAT REDUCTION BEST BE ACHIEVED?

The target of more than halving the production and consumption of farmed meat and milk over the coming decades in developed countries should be considered the minimum action that is required. But this target will require careful management of change in order to protect the livelihoods of farmers and associated businesses and the purchasing power of lower-income consumers. We propose that the following steps, involving individuals, industry, governments and international cooperation, need to be considered in order to achieve this necessary transition.

7.1

INCORPORATING CARBON COSTS INTO PRODUCTION & CONSUMPTION OF ANIMAL FOODS

Compassion in World Farming agrees with the Stern Review that: ‘The first essential element of carbon change policy is carbon pricing,’52 and with the FAO that: ‘A top priority is to achieve prices and fees that reflect the full environmental costs [of livestock production], including all externalities …[E]conomic and environmental externalities should be built into prices by selective taxing and/or fees for resource use, inputs and wastes’.14 This requirement means that the production costs and consumer prices of meat, milk and eggs should reflect their real environmental costs in terms of their global warming potential. This adjustment would increase the price of animal-based foods relative to most plant-based foods. It would discourage overconsumption of animal-based foods and encourage higher consumption of plant-based foods that have a lower global warming potential.

7.2

SUPPORT FOR CONSUMER DECISION-MAKING ON DIET & CARBON FOOTPRINT

A significant proportion of consumers now believe that an individual has to take responsibility for his or her carbon footprint. For this to happen in relation to food choices, consumers need accurate and standardised information about the carbon footprint of meat and milk products.

44

Calculations of the global warming potential of general classes of products have already been made by the European Commission.7 Organisations such as the Carbon Trust in the UK are coordinating industry and retailer efforts to calculate the carbon footprint of products and achieve standardised carbon auditing and labeling systems for consumers.75 Again in the UK, the Royal Society of Arts has proposed an individual carbon credit scheme that could operate in a similar way to a bank debit card.76 These organisations should be encouraged to include the majority GHG emissions associated with livestock products (methane and nitrous oxide) at an early stage. It is also important that auditing and labeling schemes include other important areas of consumer concern, such as Fair Trade, environment and animal welfare.77

7.3 TARGETS FOR REDUCTION IN LIVESTOCK PRODUCTION Although action by industry and individuals will be important, we foresee that livestock reduction targets will also need to be set. These could be EU-wide and incorporated into a strengthened European Emissions Trading Scheme or coordinated by the OECD Trade and Agriculture Directorate.

7.4

GOVERNMENTAL FISCAL INCENTIVES FOR MEAT REDUCTION

Fiscal incentives will be essential to manage the transition to lower volume, higher welfare animal farming by supporting farmers while discouraging overproduction and over-consumption. These incentives could take the form of direct taxes on meat consumption and tax advantages or direct support for low-density, free-range and organic animal farming. They could include ‘green taxes’ on fertiliser, pesticide and herbicide use and on the production of human-edible crops that are used or sold for animal feed.

7.5

PROTECTING PURCHASING POWER OF LOW-INCOME CONSUMERS

Low density, high welfare animal farming generally involves some increase in production costs compared to intensive farming. However, it seems likely that retailers currently put a higher price premium on some free-range and organic products than is justified by the actual difference in production and distribution costs. It would be necessary to discourage any such practice and to make financial support arrangements for low-income consumers. The large savings envisaged in health care costs as a result of reduced meat and dairy consumption and increased consumption of vegetables and fruit could be used to finance these changes.

7.6

STRENGTHENING STATUTORY ANIMAL WELFARE STANDARDS

In order to support the transition to low-density, high welfare animal farming, the current legal animal welfare standards would need to be upgraded to bring them up to the current level of the best free-range and organic farmers. A number of possible benchmarks already exist internationally for high-welfare livestock production standards (for example, in the UK, the Soil Association standards for livestock might be one possibility). In addition, all imported meat, milk and egg products would need to be required to meet these welfare standards, in order to avoid intensively-produced imports from undermining the meat reduction strategy.

45

It will be important that consumers are made aware of the large improvement in welfare standards associated with the meat reduction strategy. The European Commission could take on the task of disseminating this information.

7.7

LOCALISATION OF PRODUCTION AND CONSUMPTION

It will also be necessary to reduce transport-related CO2 emissions and discourage the import of humanedible animal feed, for example from deforested areas in South America. For this reason, the entire animal production chain should be localised as far as possible. This should include the use of feed grown and processed locally, local slaughtering and short-range distribution and consumption of animal products. The popularity of ‘farmers’ markets’ suggests that both farmers and consumers would support this policy. It would also be likely to bring economic and social benefits to local communities.

8.0

CONCLUSIONS AND RECOMMENDATIONS: COMBATING CLIMATE CHANGE THROUGH HIGH ANIMAL WELFARE FARMING IN EUROPE

The evidence presented in this report has shown that GHG emissions related to livestock production are one of the major potential causes of human-induced global warming. While comparable in magnitude of emissions to transport, the livestock source has not so far received the policy attention merited by its size and it has been relatively neglected by current governmental and intergovernmental targets and carbon pricing schemes that focus on energy-related CO2 emissions. If the projected doubling in global meat production takes place (mostly in poor and developing countries), methane and nitrous oxide emission from the digestion and manure of animals will continue to rise steeply, the demand for feed-crops will lead to further deforestation, overuse of scarce water resources, competition for arable land, damage to soil fertility and desertification of grazing land. These trends can only exacerbate the unavoidable effects of climate change, such as floods, drought and harvest failures. Resource conflicts, human conflicts and human and animal suffering are almost certain to be increased by current livestock production trends. The majority of the GHG emissions due to livestock, even in developed countries where energy use is higher, come from the natural biological processes of farmed animals. Technical ways of reducing these types of emissions are limited, costly and unlikely to provide the short-term emission reductions in developed countries that are needed if eventual global warming is to be limited to 2ºC. Further intensification of animal production as a means of reducing livestock GHGs per unit of product would be unethical and politically unacceptable to the European public who are increasingly concerned about animal welfare standards and environmental issues such as soil and water pollution, biodiversity on farmland and conservation of landscape. Intensification is also implausible as a short-term strategy, since pig and poultry production is largely already industrialised in developed countries. Meat and other animal products are currently under-priced in relation to their real costs to the environment and to animal welfare and to their impact on climate change. An effective mitigation policy requires that the full carbon costs of the production and consumption of meat are reflected in prices.

46

Compassion in World Farming believes that there is now an opportunity for constructive change that will make a significant contribution to reducing global GHG emissions while also benefiting animal welfare, human health and nutrition and the environment: The most effective and fastest-acting strategy for reducing livestock-related emissions globally is a planned and well-managed reduction in livestock production and consumption in developed countries, where there is already considerable overconsumption of meat and milk products. Meat and milk are currently under-priced in relation to their real environmental and carbon costs. Under this proposal, consumers would eat a lower volume of higher quality meat and milk, preferably from local farmers. Farmers would earn a premium for their products and higher prices would reflect the carbon costs of consuming meat and milk. A reduction in meat and dairy consumption is one of the quickest, simplest and least expensive ways in which an individual can reduce his or her carbon footprint in a developed society. Studies have shown that reducing meat consumption is equivalent to an individual cutting out hundreds of kilometres of car travel or switching to a carbonefficient hybrid car. A meat reduction strategy would enable existing farmers to reduce stocking density, move from intensive to extensive methods and raise animal welfare standards up to the best free-range and organic farming standards of today, while protecting their livelihoods. Imported products would be required to meet the same standards. Governmental and intergovernmental targets and incentives for both producers and consumers would be needed to support this transition, including protecting the purchasing power of low-income consumers. In line with current European and UK GHG reduction targets, livestock production and consumption in developed countries should be reduced to one third below current levels by 2020 and to 60% below current levels by 2050. These reductions may need to be increased further in light of scientific evidence. The increasing amount of evidence linking meat consumption with certain serious human health problems may require the adoption of a more stringent target for a reduction in meat consumption. Fast-rising livestock emissions in developing countries, which on average consume a small fraction per capita of animal-based food compared to rich countries, would need to be re-assessed by those countries when their domestic nutritional needs have been met.

47

In both developing and developed countries, all technical and management options such as improved manure storage and spreading methods, reduction and better targeting of fertiliser use, restoration of soil carbon, re-forestation and use of renewable energy sources should be pursued urgently. The benefits of this strategy are many, in addition to going a long way to meet the urgent task of reducing GHG emissions: -

A significant reduction consumption of meat and certain dairy products would improve public health and reduce the prevalence of obesity, certain heart conditions and cancers, and related health care costs. (A reduction of one-third would be equivalent to an individual who eats meat daily eating meat on only five days a week, or alternatively reducing portion sizes of meat and dairy products and substituting plant-based foods such as pulses, grains, vegetables and fruit.)

-

Localisation of animal production and consumption would support rural communities and businesses.

-

Reduction in demand for animal feed would allow a reduction in the intensity of arable farming and increase farmland biodiversity.

-

The strategy would also lead to the end of factory farming of animals and facilitate a revolution in standards of farm animal welfare.

In order to achieve a global and proportionate reduction in the production and consumption of meat and dairy products, Compassion in World Farming calls on all governments to negotiate an International Treaty on Meat and Dairy Reduction, or to incorporate meat and dairy reduction targets or production caps into any future climate change agreement. Such a treaty or agreement will set fair reduction targets for high-income countries, while allowing the poorer developing countries to enhance their small-scale livestock farming.

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APPENDIX PRODUCTION AND CONSUMPTION OF ANIMAL-BASED FOODS TABLE A.1: Current regional quantities of animal protein in human diet and increase between 1980 2002 (% increase in brackets) Source: Steinfeld et al, 2006, Table 2.4

35

The amount of animal protein (meat, milk and eggs) in diets increased much more than the total protein in diets over the 20 years from 1980 to 2002 in Latin America, developing Asia (ie: excluding Japan) and in industrialised countries and the world average. There are still large differences between average consumption in Africa, the Near East and developing Asia, including China, and industrialised countries, implying that very large growths in the global consumption of animal protein may occur in future. Protein from animal products

All protein (g/person/day) and %

(g/person/day) and % increase

increase between 1980 and 2002

between 1980 - 2002 1980

2002

1980

2002

Sub-Saharan Africa

10.4

9.3

53.9

55.1

Near East

18.2

18.1

76.3

80.5

L America & Caribbean

27.5

34.1 (+24%)

69.8

77.0 (+10%)

Asia developing

7.0

16.2 (+131%)

53.4

68.9 (+29%)

Industrialised countries

50.8

56.1 (+10%)

95.8

106.4 (+1%)

World

20.0

24.3 (+22%)

66.9

75.3 (+13%)

TABLE A.2: Consumption of meat in selected countries Source: FAOSTAT 1 2005

Consumption in 2005: g per person per day Brazil

China

India

UK

USA

Bovine meat

57.2

15.1

6.0

45.6

62.6

Chicken meat

93.9

21.8

4.7

73.3

121.4

Pig meat

36.5

104.5

1.2

59.3

48.1

Sheep and goat meat

1.8

10.5

1.7

16.2

1.4

Total of these meats

189.4

151.9

13.7

194.4

233.5

69

55

5

71

85

Total of these meats in kg/year Note: duck, goose and turkey meats not included.

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TABLE A.3: World consumption of animal-based food 2005 in tonnes Source: FAOSTAT, 2006. 1 (FAOSTAT 2007) Considering only meat and eggs, pig meat is the most consumed (32.5% of total) followed by chicken meat (22.4%), followed by cattle meat (19%) and eggs (almost 19%). Milk consumed is mainly cow milk (and buffalo milk in India). Milk quantities given in the table below are for liquid milk and therefore tonnage is large compared to meat. Animal product

Numbers of

Consumption 2005

Consumption as

Consumption

animals used in

(tonnes)

% of total

as % of meat,

production of meat

eggs and

and eggs [2]

liquid milk [3]

year 2005 [1]

Cattle meat (ex buffalo)

299 million

60.2 million

19.1

6.5

Pig meat

1.3 billion

102.4 million

32.5

11.0

Chicken meat

48.1 billion

70.5 million

22.4

7.6

Duck & goose meat

2.5 billion

5.8 million

1.8

0.6

Hen eggs

5.6 billion

59.4 million

18.9

6.4

Sheep meat

543 million

8.5 million

2.7

0.9

Goat meat

371 million

4.6 million

1.5

0.5

Buffalo meat

22 million

3.2 million

1.0

0.3

314.6 million

100

33.7

Total meat & egg consumption Cow milk [3]

239 million

529.7 million [3]

56.8

Buffalo milk

54 million

67.4 million (mainly

7.2

India) Sheep milk

186 million

8.6 million

0.9

Goat milk

151 million

12.4 million

1.3

Total including milk

932.7 million

Notes: [1] The number of meat animals consumed per year is higher than the number of animals living at any one time, e.g.: for commercial chickens there may be six ‘crops’ per year since the birds are slaughtered at around six weeks old. Some of the animals counted by FAO in each category are likely to be dualpurpose (ie: they produce both meat and eggs or meat and milk). [2] Rabbit, camel and horse meat not included in TABLE A.3. [3] The tonnage of milk is large but mainly consists of water (cow milk typically contains 3-4% fat, 4.5% lactose and around 3% protein by weight, ie: around 88% water by weight). One tonne of milk dry matter approximately equals 10,000 litres of liquid milk. This means that dairy production requires large quantities of water, over 100 litres a day per cow and increasing in higher temperatures. 11

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